KR20220056148A - Mesenchymal stem cells capable of improving tumor targeting and mass production of viruses - Google Patents

Mesenchymal stem cells capable of improving tumor targeting and mass production of viruses Download PDF

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KR20220056148A
KR20220056148A KR1020210144299A KR20210144299A KR20220056148A KR 20220056148 A KR20220056148 A KR 20220056148A KR 1020210144299 A KR1020210144299 A KR 1020210144299A KR 20210144299 A KR20210144299 A KR 20210144299A KR 20220056148 A KR20220056148 A KR 20220056148A
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cancer
e1b55k
virus
mesenchymal stem
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송재진
최수진
홍정아
최혜진
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연세대학교 산학협력단
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Abstract

The present invention relates to a mesenchymal stem cell (MSC) for a virus carrier and virus propagation. More specifically, the present invention relates to the production of MSCs capable of controlling the timing of the production and release of viruses, thereby enabling improved tumor targeting and mass production of viruses. In addition, the MSCs of the present invention can fundamentally block tumorigenicity, and controls the timing of the production and release of viruses so as to enable the viruses to be produced and released at a desired timing, thereby resulting in guaranteed safety and a maximized antitumor effect.

Description

종양 타겟팅 향상 및 바이러스 대량 생산을 가능한 중간엽줄기세포{Mesenchymal stem cells capable of improving tumor targeting and mass production of viruses}Mesenchymal stem cells capable of improving tumor targeting and mass production of viruses

본 발명은 바이러스 전달체 및 바이러스 증식을 위한 중간엽 줄기세포의 종양 타겟팅 향상 및 바이러스 대량 생산을 가능하도록 바이러스 생산과 방출 시기 제어 가능한 중간엽 줄기세포 제작에 관한 것이다.The present invention relates to the production of mesenchymal stem cells capable of controlling virus production and release timing to improve tumor targeting of mesenchymal stem cells for virus delivery and virus propagation and to enable mass production of viruses.

수포성 구내염 바이러스(vesicular stomatitis virus)의 경우 정맥 투여 바이러스 (input virus) 대비 종양 타겟 도달율이 24시간 안에 0.01%로 보고되었듯이 [비특허문헌 1]. 바이러스 정맥 주사 시 타겟으로의 매우 낮은 전달효율이 가장 큰 제약 요소였다. In the case of vesicular stomatitis virus, compared to the intravenous virus (input virus), the rate of reaching the tumor target was reported to be 0.01% within 24 hours [Non-Patent Document 1]. The very low delivery efficiency to the target during intravenous injection of the virus was the biggest constraint.

암 환자의 사망율의 대다수는 전이성 종양에 기인하므로 투여된 바이러스 대비 종양으로의 향성(tropism) 및 충분한 양의 종양 살상(oncolytic) 바이러스가 종양에 전달되는 것이 필수적이다. Since the majority of mortality rates in cancer patients are due to metastatic tumors, it is essential that tropism and sufficient amount of oncolytic virus be delivered to the tumor compared to the administered virus.

하지만, 혈관 내 주사 시 대부분의 바이러스들은 간의 Kupffer cells에 흡수되거나 mechanical deposition에 의해 재빨리 제거되며, 혈관내 바이러스 중화항체와 complement에 의해 쉽게 파괴되며, 또한 혈관내 바이러스들이 종양 부위에서 방출되는 비율은 상당히 낮은 문제가 있다. 이러한 문제점으로 인하여 특히 아데노바이러스 단독을 정맥 주사로 도입하는 것은 효과를 기대할 수 없었다. However, during intravascular injection, most viruses are absorbed by Kupffer cells of the liver or rapidly eliminated by mechanical deposition, and are easily destroyed by intravascular virus neutralizing antibodies and complement. There is a low problem. In particular, the introduction of adenovirus alone intravenously due to these problems could not be expected to be effective.

해결책으로는 바이러스의 유전적 변형을 일으키거나 나노기술도입 그리고 종양 부위로의 향성(tropism)이 있는 중간엽 줄기세포 (mesenchymal stem cell)를 사용하는 것 등이 있다. 특히, 2010년을 전후로 중간엽줄기세포 등을 비롯한 종양 향성이 있는 세포들에 대한 연구가 수행되어 왔다[비특허문헌 2]. 하지만, 윤리적 기술적 편리성, 낮은 면역원성, 유전적 안정성 등에서 장점이 많은 중간엽줄기세포 (MSC)이지만 MSC에 대한 아데노바이러스의 감염율과 복제율 저하 문제가 대두되었다.Solutions include genetic modification of the virus, the introduction of nanotechnology, and the use of mesenchymal stem cells with tropism to the site of the tumor. In particular, studies on tumor-prone cells including mesenchymal stem cells have been conducted around 2010 [Non-Patent Document 2]. However, although mesenchymal stem cells (MSCs) have many advantages such as ethical and technological convenience, low immunogenicity, and genetic stability, the problem of adenovirus infection rate and replication rate decrease for MSC has emerged.

종양 살상 아데노바이러스의 전달체(carrier)와 증식체(amplifier)가 되기 위해서는 MSC에 대한 감염과 복제가 일정 수준 이상으로 유지되어야 하는데 이러한 문제를 해결하기 위해, 본 발명자들은 유전적으로 변형시킨 MSC를 제작하여 국내 특허 등록받은 바 있다[특허 문헌 2]. 하지만, 이 MSC 역시 그러나 계대 증식(passage extension)이 용이하지 않았으며 passage 경과함에 따라 세포주 상태가 나빠짐을 확인하였다. In order to become a carrier and amplifier of oncolytic adenovirus, infection and replication of MSCs must be maintained at a certain level or more. To solve this problem, the present inventors produced genetically modified MSCs and A domestic patent has been registered [Patent Document 2]. However, it was confirmed that these MSCs also did not undergo passage extension easily and the cell line state deteriorated as passage passed.

또한, 비특허문헌 3는 종양 살상 바이러스 전달용 MSC의 혈관내 전달은 다발성 뇌 종양 치료 접근 가능성을 확인하였으나, MSC의 종양성장 가능성 등의 문제가 있다.In addition, Non-Patent Document 3 confirms that intravascular delivery of MSCs for oncolytic virus delivery has access to treatment for multiple brain tumors, but has problems such as the possibility of MSC tumor growth.

한편. 종양으로 이동 후 원하는 시점에 생산이 증가된 바이러스를 일시에 방출하는 플랫폼을 구축한 기술이 보고된 바 있다[비특허문헌 4] 이는 바이러스 전달체로서 MSC 사용 시 세포사멸을 유도하는 유전자를 탑재한 carrier 세포(MSC)가 종양 부위로 도달되기 전에 일찍 용해되어 바이러스를 방출함으로써 야기될 수 있는 다양한 문제들, 무엇보다도 안전성 문제 등이 제기되었다. Meanwhile. A technology has been reported that establishes a platform that temporarily releases a virus with increased production at a desired time after moving to a tumor [Non-Patent Document 4] This is a carrier loaded with a gene that induces apoptosis when MSC is used as a virus carrier Various problems that can be caused by cells (MSCs) being lysed early to release the virus before reaching the tumor site, above all, safety issues have been raised.

따라서, 현실적으로 암에 의한 대부분의 사망이 재발 및 전이에 의해서 일어나는 현실에서 종양 살상 바이러스에 의한 종양 치료에 있어서 아직까지 해결되지 않는 주된 장애물들을 극복할 수 있는 기술이 필요한 실정이다.Therefore, in reality, most deaths due to cancer are caused by recurrence and metastasis, and there is a need for a technology capable of overcoming the main obstacles that have not been solved yet in the treatment of tumors by oncolytic viruses.

국내 등록 특허 제10-2169798호 (2020.10.26)Domestic Registered Patent No. 10-2169798 (2020.10.26)

Silva, N et al., Double trouble for tumors: Exploiting the tumor microenvironment to enhance anticancer effect of oncolytic viruses, Cytokine & Growth Factor Reviews 21: 135, 2010Silva, N et al., Double trouble for tumors: Exploiting the tumor microenvironment to enhance anticancer effect of oncolytic viruses, Cytokine & Growth Factor Reviews 21: 135, 2010 Xia, X et al, Mesenchymal stem cells as carriers and amplifiers in CRAd delivery to tumors, Molecular Cancer 10: 134, 2011Xia, X et al, Mesenchymal stem cells as carriers and amplifiers in CRAd delivery to tumors, Molecular Cancer 10: 134, 2011 Kerrigan BCP, Shimizu Y, Andreeff M, Lang FF. Mesenchymal stromal cells for the delivery of oncolytic viruses in gliomas. Cytotherapy 2017; 19:445-457Kerrigan BCP, Shimizu Y, Andreeff M, Lang FF. Mesenchymal stromal cells for the delivery of oncolytic viruses in gliomas. Cytotherapy 2017; 19:445-457 Nakashima H, Kaur B, Chiocca EA. Directing systemic oncolytic viral delivery to tumors via carrier cells. Cytokine Growth Factor Rev 2010; 21:119-126Nakashima H, Kaur B, Chiocca EA. Directing systemic oncolytic viral delivery to tumors via carrier cells. Cytokine Growth Factor Rev 2010; 21:119-126

이에, 본 발명자들은 상기와 같은 문제점을 해결하기 위하여 연구 노력한 결과, 바이러스 전달체 및 바이러스 증식을 위한 중간엽 줄기세포의 종양 타겟팅 향상 및 바이러스 대량 생산을 가능하도록 바이러스 생산과 방출 시기 제어 가능한 중간엽 줄기세포를 개발함으로써 본 발명을 완성하게 되었다.Therefore, as a result of research efforts to solve the above problems, the present inventors have improved the tumor targeting of mesenchymal stem cells for virus delivery and virus propagation and mesenchymal stem cells capable of controlling virus production and release timing to enable mass production of viruses By developing the present invention was completed.

따라서, 본 발명은 GRP78(Glucose regulated protein 78) 유전자가 도입된, 종양 표적능이 향상된 종양 살상 바이러스 전달용 중간엽 줄기세포를 제공하는데 그 목적이 있다.Accordingly, an object of the present invention is to provide a mesenchymal stem cell for delivery of an oncolytic virus having an improved tumor targeting ability, into which the GRP78 (glucose regulated protein 78) gene is introduced.

또한, 본 발명은 발현유도물질에 의해 발현이 유도되도록 E1B55K 유전자가 도입된 종양 살상 바이러스 전달용 중간엽 줄기세포를 제공하는데 다른 목적이 있다.Another object of the present invention is to provide mesenchymal stem cells for oncolytic virus delivery into which the E1B55K gene is introduced so that expression is induced by an expression inducer.

또한, 본 발명은 GRP78(Glucose regulated protein 78) 유전자 및 E1B55K 유전자를 포함하며, 상기 E1B55K유전자는 발현유도물질에 의해 발현되는 것인 종양 살상 바이러스 전달용 중간엽 줄기세포를 제공하는데 또 다른 목적이 있다.In addition, the present invention includes a GRP78 (glucose regulated protein 78) gene and an E1B55K gene, wherein the E1B55K gene is expressed by an expression inducer Another object is to provide mesenchymal stem cells for oncolytic virus delivery.

또한, 본 발명은 상기 중간엽 줄기세포 및 종양 살상 바이러스를 포함하는 항암 유전자 전달용 조성물을 제공하는데 또 다른 목적이 있다.Another object of the present invention is to provide a composition for anticancer gene delivery comprising the mesenchymal stem cells and oncolytic virus.

또한, 본 발명은 상기 중간엽 줄기세포 및 종양 살상 바이러스를 포함하는 항암용 약제학적 조성물을 제공하는데 또 다른 목적이 있다.In addition, another object of the present invention is to provide a pharmaceutical composition for anticancer comprising the mesenchymal stem cells and oncolytic virus.

또한, 본 발명은 상기 중간엽 줄기세포 및 종양 살상 바이러스를 포함하는 암 진단용 조성물을 제공하는데 또 다른 목적이 있다.Another object of the present invention is to provide a composition for diagnosing cancer comprising the mesenchymal stem cells and oncolytic virus.

또한, 본 발명은 치료상의 유효량의, 상기 중간엽 줄기세포 및 종양 살상 바이러스를 포함하는 약제학적 조성물을 대상체에 투여하는 것을 포함하는 암 치료 방법을 제공하는데 또 다른 목적이 있다.Another object of the present invention is to provide a method for treating cancer comprising administering to a subject a therapeutically effective amount of a pharmaceutical composition comprising the mesenchymal stem cells and the oncolytic virus.

바이러스 단독에 의한 종양 치료 방식에서 제기되는 3가지 큰 어려움은 다음과 같다.The three major challenges posed by virus-only tumor treatment are:

첫째, 종양살상 아데노바이러스(oncolytic adenovirus)에 대한 circulating antiviral 항체에 의한 파괴, 둘째, 간, 비장 등의 다른 비종양 조직에 의한 비특이적 흡착, 셋째, 혈관으로부터 종양부위로의 바이러스 유출이 거의 일어나지 않는다는 점이다. First, destruction by circulating antiviral antibody against oncolytic adenovirus, second, non-specific adsorption by other non-tumor tissues such as liver and spleen, third, virus leakage from blood vessels to the tumor site hardly occurs am.

이러한 바이러스 치료(virotherapy)의 근본적인 문제를 극복하기 위해서 종양 살상 바이러스의 전신 혈액 내 운반을 용이하게 하기 위하여 중간엽 줄기세포를 세포 전달체(cell carrier)로 사용하였으며, 바이러스의 운반 이외에도 타겟 종양 부위로 이동 중 생산된 대량의 바이러스에 의한 효과적인 항종양 작용을 위해 유전적으로 변형시킨 중간엽줄기세포주 (MSC)를 개발하였다.To overcome the fundamental problem of virotherapy, mesenchymal stem cells were used as a cell carrier to facilitate systemic blood transport of oncolytic viruses, and in addition to transporting viruses, they moved to the target tumor site. A genetically modified mesenchymal stem cell line (MSC) was developed for effective anti-tumor action by a large amount of virus produced in the middle.

본 발명은 바이러스 전달체 및 바이러스 증식을 위한 중간엽 줄기세포의 종양 타겟팅 향상 및 바이러스 대량 생산을 가능하도록 바이러스 생산과 방출 시기 제어 가능한 중간엽 줄기세포 제작에 관한 것이다.The present invention relates to the production of mesenchymal stem cells capable of controlling virus production and release timing to improve tumor targeting of mesenchymal stem cells for virus delivery and virus propagation and to enable mass production of viruses.

이하 본 발명을 더욱 상세하게 설명한다.Hereinafter, the present invention will be described in more detail.

본 발명은 인간의 GRP78 (Glucose regulated protein 78) 유전자 (진뱅크 NM_005347)가 도입된, 종양 살상 바이러스 전달용 중간엽 줄기세포를 포함한다. The present invention includes human GRP78 (Glucose regulated protein 78) gene (GenBank NM_005347) introduced, mesenchymal stem cells for oncolytic virus delivery.

또한, 바이러스 전달체로 사용되는 중간엽 줄기세포에 GRP78 유전자를 도입함으로써 종양 표적능이 향상된 종양 살상 바이러스 전달용 중간엽 줄기세포를 제공한다.In addition, it provides mesenchymal stem cells for oncolytic virus delivery with improved tumor targeting ability by introducing the GRP78 gene into mesenchymal stem cells used as virus carriers.

상기 GRP78 유전자는 글루코오스 조절 단백질 78 유전자로서, 세포의 운동성(motility)을 증가시켜 세포 침윤을 증가시킨다는 역할에 대해서는 이미 알려져 있으며, 이 유전자 서열은 진뱅크 NM_005347 서열번호 1(인간)에 나타낸 바와 같다. 본 발명에서는 종양 회귀 마커(tumor homing marker)로 종양 표적능을 향상시키는 역할을 한다. The GRP78 gene is a glucose regulatory protein 78 gene, which is already known for its role in increasing cell invasion by increasing cell motility, and this gene sequence is as shown in GenBank NM_005347 SEQ ID NO: 1 (human). In the present invention, it serves to improve tumor targeting ability as a tumor homing marker.

[서열번호 1][SEQ ID NO: 1]

atg aagctctccc tggtggccgc gatgctgctg ctgctcagcg cggcgcgggc cgaggaggag gacaagaagg aggacgtggg cacggtggtc ggcatcgacc tggggaccac ctactcctgc gtcggcgtgt tcaagaacgg ccgcgtggag atcatcgcca acgatcaggg caaccgcatc acgccgtcct atgtcgcctt cactcctgaa ggggaacgtc tgattggcga tgccgccaag aaccagctca cctccaaccc cgagaacacg gtctttgacg ccaagcggct catcggccgc acgtggaatg acccgtctgt gcagcaggac atcaagttct tgccgttcaa ggtggttgaa aagaaaacta aaccatacat tcaagttgat attggaggtg ggcaaacaaa gacatttgct cctgaagaaa tttctgccat ggttctcact aaaatgaaag aaaccgctga ggcttatttg ggaaagaagg ttacccatgc agttgttact gtaccagcct attttaatga tgcccaacgc caagcaacca aagacgctgg aactattgct ggcctaaatg ttatgaggat catcaacgag cctacggcag ctgctattgc ttatggcctg gataagaggg agggggagaa gaacatcctg gtgtttgacc tgggtggcgg aaccttcgat gtgtctcttc tcaccattga caatggtgtc ttcgaagttg tggccactaa tggagatact catctgggtg gagaagactt tgaccagcgt gtcatggaac acttcatcaa actgtacaaa aagaagacgg gcaaagatgt caggaaagac aatagagctg tgcagaaact ccggcgcgag gtagaaaagg ccaaacgggc cctgtcttct cagcatcaag caagaattga aattgagtcc ttctatgaag gagaagactt ttctgagacc ctgactcggg ccaaatttga agagctcaac atggatctgt tccggtctac tatgaagccc gtccagaaag tgttggaaga ttctgatttg aagaagtctg atattgatga aattgttctt gttggtggct cgactcgaat tccaaagatt cagcaactgg ttaaagagtt cttcaatggc aaggaaccat cccgtggcat aaacccagat gaagctgtag cgtatggtgc tgctgtccag gctggtgtgc tctctggtga tcaagataca ggtgacctgg tactgcttga tgtatgtccc cttacacttg gtattgaaac tgtgggaggt gtcatgacca aactgattcc aaggaacaca gtggtgccta ccaagaagtc tcagatcttt tctacagctt ctgataatca accaactgtt acaatcaagg tctatgaagg tgaaagaccc ctgacaaaag acaatcatct tctgggtaca tttgatctga ctggaattcc tcctgctcct cgtggggtcc cacagattga agtcaccttt gagatagatg tgaatggtat tcttcgagtg acagctgaag acaagggtac agggaacaaa aataagatca caatcaccaa tgaccagaat cgcctgacac ctgaagaaat cgaaaggatg gttaatgatg ctgagaagtt tgctgaggaa gacaaaaagc tcaaggagcg cattgatact agaaatgagt tggaaagcta tgcctattct ctaaagaatc agattggaga taaagaaaag ctgggaggta aactttcctc tgaagataag gagaccatgg aaaaagctgt agaagaaaag attgaatggc tggaaagcca ccaagatgct gacattgaag acttcaaagc taagaagaag gaactggaag aaattgttca accaattatc agcaaactct atggaagtgc aggccctccc ccaactggtg aagaggatac agcagaaaaa gatgagttgt agatg aagctctccc tggtggccgc gatgctgctg ctgctcagcg cggcgcgggc cgaggaggag gacaagaagg aggacgtggg cacggtggtc ggcatcgacc tggggaccac ctactcctgc gtcggcgtgt tcaagaacgg ccgcgtggag atcatcgcca acgatcaggg caaccgcatc acgccgtcct atgtcgcctt cactcctgaa ggggaacgtc tgattggcga tgccgccaag aaccagctca cctccaaccc cgagaacacg gtctttgacg ccaagcggct catcggccgc acgtggaatg acccgtctgt gcagcaggac atcaagttct tgccgttcaa ggtggttgaa aagaaaacta aaccatacat tcaagttgat attggaggtg ggcaaacaaa gacatttgct cctgaagaaa tttctgccat ggttctcact aaaatgaaag aaaccgctga ggcttatttg ggaaagaagg ttacccatgc agttgttact gtaccagcct attttaatga tgcccaacgc caagcaacca aagacgctgg aactattgct ggcctaaatg ttatgaggat catcaacgag cctacggcag ctgctattgc ttatggcctg gataagaggg agggggagaa gaacatcctg gtgtttgacc tgggtggcgg aaccttcgat gtgtctcttc tcaccattga caatggtgtc ttcgaagttg tggccactaa tggagatact catctgggtg gagaagactt tgaccagcgt gtcatggaac acttcatcaa actgtacaaa aagaagacgg gcaaagatgt caggaaagac aatagagctg tgcagaaact ccggcgcgag gtagaaaagg ccaaacgggc cctgtcttct cagcat caag caagaattga aattgagtcc ttctatgaag gagaagactt ttctgagacc ctgactcggg ccaaatttga agagctcaac atggatctgt tccggtctac tatgaagccc gtccagaaag tgttggaaga ttctgatttg aagaagtctg atattgatga aattgttctt gttggtggct cgactcgaat tccaaagatt cagcaactgg ttaaagagtt cttcaatggc aaggaaccat cccgtggcat aaacccagat gaagctgtag cgtatggtgc tgctgtccag gctggtgtgc tctctggtga tcaagataca ggtgacctgg tactgcttga tgtatgtccc cttacacttg gtattgaaac tgtgggaggt gtcatgacca aactgattcc aaggaacaca gtggtgccta ccaagaagtc tcagatcttt tctacagctt ctgataatca accaactgtt acaatcaagg tctatgaagg tgaaagaccc ctgacaaaag acaatcatct tctgggtaca tttgatctga ctggaattcc tcctgctcct cgtggggtcc cacagattga agtcaccttt gagatagatg tgaatggtat tcttcgagtg acagctgaag acaagggtac agggaacaaa aataagatca caatcaccaa tgaccagaat cgcctgacac ctgaagaaat cgaaaggatg gttaatgatg ctgagaagtt tgctgaggaa gacaaaaagc tcaaggagcg cattgatact agaaatgagt tggaaagcta tgcctattct ctaaagaatc agattggaga taaagaaaag ctgggaggta aactttcctc tgaagataag gagaccatgg aaaaagctgt agaagaaaag attgaatggc tggaa agcca ccaagatgct gacattgaag acttcaaagc taagaagaag gaactggaag aaattgttca accaattatc agcaaactct atggaagtgc aggccctccc ccaactggtg aagaggatac agcagaaaaa gatgagttgt ag

본 발명에서는 상기 GRP78 유전자로 인해 종양 향성이 향상되었음을 확인하였으며, 특히 종양 외에 다른 장기에는 흡착 없이 종양 조직 부위로 바이러스가 전달되었다. In the present invention, it was confirmed that the tumor tropism was improved due to the GRP78 gene, and in particular, the virus was delivered to the tumor tissue site without adsorption to organs other than the tumor.

이러한 특정 유전자 도입을 용이하도록 하기 위해 인간 중간엽 줄기세포의 경우 계대 증식이 용이하지 않으나, 이를 극복하기 위해 세포 증식을 유도하는 TERT(telomerase reverse transcriptase) 유전자를 추가로 도입할 수 있다.In the case of human mesenchymal stem cells to facilitate the introduction of these specific genes, passage proliferation is not easy, but to overcome this, a telomerase reverse transcriptase (TERT) gene that induces cell proliferation can be additionally introduced.

상기 TERT 유전자는 텔로머라제 역전사효소 유전자로서, 이 유전자 서열은 진뱅크 NM_198253, 서열번호 2(인간)에 나타낸 바와 같다.The TERT gene is a telomerase reverse transcriptase gene, and the gene sequence is as shown in GenBank NM_198253, SEQ ID NO: 2 (human).

[서열번호 2][SEQ ID NO: 2]

atgccgcgcgc tccccgctgc cgagccgtgc gctccctgct gcgcagccac taccgcgagg tgctgccgct ggccacgttc gtgcggcgcc tggggcccca gggctggcgg ctggtgcagc gcggggaccc ggcggctttc cgcgcgctgg tggcccagtg cctggtgtgc gtgccctggg acgcacggcc gccccccgcc gccccctcct tccgccaggt gtcctgcctg aaggagctgg tggcccgagt gctgcagagg ctgtgcgagc gcggcgcgaa gaacgtgctg gccttcggct tcgcgctgct ggacggggcc cgcgggggcc cccccgaggc cttcaccacc agcgtgcgca gctacctgcc caacacggtg accgacgcac tgcgggggag cggggcgtgg gggctgctgc tgcgccgcgt gggcgacgac gtgctggttc acctgctggc acgctgcgcg ctctttgtgc tggtggctcc cagctgcgcc taccaggtgt gcgggccgcc gctgtaccag ctcggcgctg ccactcaggc ccggcccccg ccacacgcta gtggaccccg aaggcgtctg ggatgcgaac gggcctggaa ccatagcgtc agggaggccg gggtccccct gggcctgcca gccccgggtg cgaggaggcg cgggggcagt gccagccgaa gtctgccgtt gcccaagagg cccaggcgtg gcgctgcccc tgagccggag cggacgcccg ttgggcaggg gtcctgggcc cacccgggca ggacgcgtgg accgagtgac cgtggtttct gtgtggtgtc acctgccaga cccgccgaag aagccacctc tttggagggt gcgctctctg gcacgcgcca ctcccaccca tccgtgggcc gccagcacca cgcgggcccc ccatccacat cgcggccacc acgtccctgg gacacgcctt gtcccccggt gtacgccgag accaagcact tcctctactc ctcaggcgac aaggagcagc tgcggccctc cttcctactc agctctctga ggcccagcct gactggcgct cggaggctcg tggagaccat ctttctgggt tccaggccct ggatgccagg gactccccgc aggttgcccc gcctgcccca gcgctactgg caaatgcggc ccctgtttct ggagctgctt gggaaccacg cgcagtgccc ctacggggtg ctcctcaaga cgcactgccc gctgcgagct gcggtcaccc cagcagccgg tgtctgtgcc cgggagaagc cccagggctc tgtggcggcc cccgaggagg aggacacaga cccccgtcgc ctggtgcagc tgctccgcca gcacagcagc ccctggcagg tgtacggctt cgtgcgggcc tgcctgcgcc ggctggtgcc cccaggcctc tggggctcca ggcacaacga acgccgcttc ctcaggaaca ccaagaagtt catctccctg gggaagcatg ccaagctctc gctgcaggag ctgacgtgga agatgagcgt gcgggactgc gcttggctgc gcaggagccc aggggttggc tgtgttccgg ccgcagagca ccgtctgcgt gaggagatcc tggccaagtt cctgcactgg ctgatgagtg tgtacgtcgt cgagctgctc aggtctttct tttatgtcac ggagaccacg tttcaaaaga acaggctctt tttctaccgg aagagtgtct ggagcaagtt gcaaagcatt ggaatcagac agcacttgaa gagggtgcag ctgcgggagc tgtcggaagc agaggtcagg cagcatcggg aagccaggcc cgccctgctg acgtccagac tccgcttcat ccccaagcct gacgggctgc ggccgattgt gaacatggac tacgtcgtgg gagccagaac gttccgcaga gaaaagaggg ccgagcgtct cacctcgagg gtgaaggcac tgttcagcgt gctcaactac gagcgggcgc ggcgccccgg cctcctgggc gcctctgtgc tgggcctgga cgatatccac agggcctggc gcaccttcgt gctgcgtgtg cgggcccagg acccgccgcc tgagctgtac tttgtcaagg tggatgtgac gggcgcgtac gacaccatcc cccaggacag gctcacggag gtcatcgcca gcatcatcaa accccagaac acgtactgcg tgcgtcggta tgccgtggtc cagaaggccg cccatgggca cgtccgcaag gccttcaaga gccacgtctc taccttgaca gacctccagc cgtacatgcg acagttcgtg gctcacctgc aggagaccag cccgctgagg gatgccgtcg tcatcgagca gagctcctcc ctgaatgagg ccagcagtgg cctcttcgac gtcttcctac gcttcatgtg ccaccacgcc gtgcgcatca ggggcaagtc ctacgtccag tgccagggga tcccgcaggg ctccatcctc tccacgctgc tctgcagcct gtgctacggc gacatggaga acaagctgtt tgcggggatt cggcgggacg ggctgctcct gcgtttggtg gatgatttct tgttggtgac acctcacctc acccacgcga aaaccttcct caggaccctg gtccgaggtg tccctgagta tggctgcgtg gtgaacttgc ggaagacagt ggtgaacttc cctgtagaag acgaggccct gggtggcacg gcttttgttc agatgccggc ccacggccta ttcccctggt gcggcctgct gctggatacc cggaccctgg aggtgcagag cgactactcc agctatgccc ggacctccat cagagccagt ctcaccttca accgcggctt caaggctggg aggaacatgc gtcgcaaact ctttggggtc ttgcggctga agtgtcacag cctgtttctg gatttgcagg tgaacagcct ccagacggtg tgcaccaaca tctacaagat cctcctgctg caggcgtaca ggtttcacgc atgtgtgctg cagctcccat ttcatcagca agtttggaag aaccccacat ttttcctgcg cgtcatctct gacacggcct ccctctgcta ctccatcctg aaagccaaga acgcagggat gtcgctgggg gccaagggcg ccgccggccc tctgccctcc gaggccgtgc agtggctgtg ccaccaagca ttcctgctca agctgactcg acaccgtgtc acctacgtgc cactcctggg gtcactcagg acagcccaga cgcagctgag tcggaagctc ccggggacga cgctgactgc cctggaggcc gcagccaacc cggcactgcc ctcagacttc aagaccatcc tggactgaatgccgcgcgc tccccgctgc cgagccgtgc gctccctgct gcgcagccac taccgcgagg tgctgccgct ggccacgttc gtgcggcgcc tggggcccca gggctggcgg ctggtgcagc gcggggaccc ggcggctttc cgcgcgctgg tggcccagtg cctggtgtgc gtgccctggg acgcacggcc gccccccgcc gccccctcct tccgccaggt gtcctgcctg aaggagctgg tggcccgagt gctgcagagg ctgtgcgagc gcggcgcgaa gaacgtgctg gccttcggct tcgcgctgct ggacggggcc cgcgggggcc cccccgaggc cttcaccacc agcgtgcgca gctacctgcc caacacggtg accgacgcac tgcgggggag cggggcgtgg gggctgctgc tgcgccgcgt gggcgacgac gtgctggttc acctgctggc acgctgcgcg ctctttgtgc tggtggctcc cagctgcgcc taccaggtgt gcgggccgcc gctgtaccag ctcggcgctg ccactcaggc ccggcccccg ccacacgcta gtggaccccg aaggcgtctg ggatgcgaac gggcctggaa ccatagcgtc agggaggccg gggtccccct gggcctgcca gccccgggtg cgaggaggcg cgggggcagt gccagccgaa gtctgccgtt gcccaagagg cccaggcgtg gcgctgcccc tgagccggag cggacgcccg ttgggcaggg gtcctgggcc cacccgggca ggacgcgtgg accgagtgac cgtggtttct gtgtggtgtc acctgccaga cccgccgaag aagccacctc tttggagggt gcgctctctg gcacgcgcca ctcccaccca tccgtgggcc gccagcacc a cgcgggcccc ccatccacat cgcggccacc acgtccctgg gacacgcctt gtcccccggt gtacgccgag accaagcact tcctctactc ctcaggcgac aaggagcagc tgcggccctc cttcctactc agctctctga ggcccagcct gactggcgct cggaggctcg tggagaccat ctttctgggt tccaggccct ggatgccagg gactccccgc aggttgcccc gcctgcccca gcgctactgg caaatgcggc ccctgtttct ggagctgctt gggaaccacg cgcagtgccc ctacggggtg ctcctcaaga cgcactgccc gctgcgagct gcggtcaccc cagcagccgg tgtctgtgcc cgggagaagc cccagggctc tgtggcggcc cccgaggagg aggacacaga cccccgtcgc ctggtgcagc tgctccgcca gcacagcagc ccctggcagg tgtacggctt cgtgcgggcc tgcctgcgcc ggctggtgcc cccaggcctc tggggctcca ggcacaacga acgccgcttc ctcaggaaca ccaagaagtt catctccctg gggaagcatg ccaagctctc gctgcaggag ctgacgtgga agatgagcgt gcgggactgc gcttggctgc gcaggagccc aggggttggc tgtgttccgg ccgcagagca ccgtctgcgt gaggagatcc tggccaagtt cctgcactgg ctgatgagtg tgtacgtcgt cgagctgctc aggtctttct tttatgtcac ggagaccacg tttcaaaaga acaggctctt tttctaccgg aagagtgtct ggagcaagtt gcaaagcatt ggaatcagac agcacttgaa gagggtgcag ctgcgggagc tgtcggaagc agaggtca gg cagcatcggg aagccaggcc cgccctgctg acgtccagac tccgcttcat ccccaagcct gacgggctgc ggccgattgt gaacatggac tacgtcgtgg gagccagaac gttccgcaga gaaaagaggg ccgagcgtct cacctcgagg gtgaaggcac tgttcagcgt gctcaactac gagcgggcgc ggcgccccgg cctcctgggc gcctctgtgc tgggcctgga cgatatccac agggcctggc gcaccttcgt gctgcgtgtg cgggcccagg acccgccgcc tgagctgtac tttgtcaagg tggatgtgac gggcgcgtac gacaccatcc cccaggacag gctcacggag gtcatcgcca gcatcatcaa accccagaac acgtactgcg tgcgtcggta tgccgtggtc cagaaggccg cccatgggca cgtccgcaag gccttcaaga gccacgtctc taccttgaca gacctccagc cgtacatgcg acagttcgtg gctcacctgc aggagaccag cccgctgagg gatgccgtcg tcatcgagca gagctcctcc ctgaatgagg ccagcagtgg cctcttcgac gtcttcctac gcttcatgtg ccaccacgcc gtgcgcatca ggggcaagtc ctacgtccag tgccagggga tcccgcaggg ctccatcctc tccacgctgc tctgcagcct gtgctacggc gacatggaga acaagctgtt tgcggggatt cggcgggacg ggctgctcct gcgtttggtg gatgatttct tgttggtgac acctcacctc acccacgcga aaaccttcct caggaccctg gtccgaggtg tccctgagta tggctgcgtg gtgaacttgc ggaagacagt ggtgaacttc cctgtag aag acgaggccct gggtggcacg gcttttgttc agatgccggc ccacggccta ttcccctggt gcggcctgct gctggatacc cggaccctgg aggtgcagag cgactactcc agctatgccc ggacctccat cagagccagt ctcaccttca accgcggctt caaggctggg aggaacatgc gtcgcaaact ctttggggtc ttgcggctga agtgtcacag cctgtttctg gatttgcagg tgaacagcct ccagacggtg tgcaccaaca tctacaagat cctcctgctg caggcgtaca ggtttcacgc atgtgtgctg cagctcccat ttcatcagca agtttggaag aaccccacat ttttcctgcg cgtcatctct gacacggcct ccctctgcta ctccatcctg aaagccaaga acgcagggat gtcgctgggg gccaagggcg ccgccggccc tctgccctcc gaggccgtgc agtggctgtg ccaccaagca ttcctgctca agctgactcg acaccgtgtc acctacgtgc cactcctggg gtcactcagg acagcccaga cgcagctgag tcggaagctc ccggggacga cgctgactgc cctggaggcc gcagccacc ctggcggactgcc

본 발명에서 MSC-TERT-GRP78 세포주를 확립하였으며, 바이러스 전달체 및 바이러스 증식을 위한 중간엽 줄기세포의 종양 타겟팅 향상을 확인하였다. 따라서, 상기 중간엽줄기세포는 종양 진단 및 치료 모두에 사용될 수 있다.MSC-TERT-GRP78 in the present invention Cell lines were established, and the improvement of tumor targeting of mesenchymal stem cells for viral transport and virus propagation was confirmed. Therefore, the mesenchymal stem cells can be used for both diagnosis and treatment of tumors.

또한, 본 발명은 발현유도물질에 의해 발현이 유도되도록 E1B55K 유전자가 도입된 종양 살상 바이러스 바이러스 전달용 중간엽 줄기세포를 제공한다.In addition, the present invention provides a mesenchymal stem cell for delivery of an oncolytic virus virus into which the E1B55K gene is introduced so that expression is induced by an expression inducer.

상기 E1B55K 유전자는 아데노바이러스의 수명 중 초기에 발현되는 E1B55K 단백질을 코딩하는 바이러스 유전자이다. 이 유전자 서열은 진뱅크 AC_000008, 서열번호 3에 나타낸 바와 같다. (첫째 줄 밑줄 표시한 a는 원래 g였으나 치환하여 KpnI site 제거함. 열 네번째줄 밑줄 표시한 t는 원래 a를 t로 치환하여 HindIII 부위 제거한 것임.)The E1B55K gene is a viral gene encoding an E1B55K protein expressed early in the lifespan of an adenovirus. This gene sequence is as shown in GenBank AC_000008, SEQ ID NO:3. (The underlined a in the first line was originally g, but the KpnI site was removed by substitution. The underlined t in the fourteenth line was originally a replaced with t and the HindIII site was removed.)

[서열번호 3][SEQ ID NO: 3]

atggagcgaaga aacccatctg agcgggg a gt acctgctgga ttttctggcc atgcatctgt ggagagcggt tgtgagacac aagaatcgcc tgctactgtt gtcttccgtc cgcccggcga taataccgac ggaggagcag cagcagcagc aggaggaagc caggcggcgg cggcaggagc agagcccatg gaacccgaga gccggcctgg accctcggga atgaatgttg tacaggtggc tgaactgtat ccagaactga gacgcatttt gacaattaca gaggatgggc aggggctaaa gggggtaaag agggagcggg gggcttgtga ggctacagag gaggctagga atctagcttt tagcttaatg accagacacc gtcctgagtg tattactttt caacagatca aggataattg cgctaatgag cttgatctgc tggcgcagaa gtattccata gagcagctga ccacttactg gctgcagcca ggggatgatt ttgaggaggc tattagggta tatgcaaagg tggcacttag gccagattgc aagtacaaga tcagcaaact tgtaaatatc aggaattgtt gctacatttc tgggaacggg gccgaggtgg agatagatac ggaggatagg gtggccttta gatgtagcat gataaatatg tggccggggg tgcttggcat ggacggggtg gttattatga atgtaaggtt tactggcccc aattttagcg gtacggtttt cctggccaat accaacctta tcctacacgg tgt t agcttc tatgggttta acaatacctg tgtggaagcc tggaccgatg taagggttcg gggctgtgcc ttttactgct gctggaaggg ggtggtgtgt cgccccaaaa gcagggcttc aattaagaaa tgcctctttg aaaggtgtac cttgggtatc ctgtctgagg gtaactccag ggtgcgccac aatgtggcct ccgactgtgg ttgcttcatg ctagtgaaaa gcgtggctgt gattaagcat aacatggtat gtggcaactg cgaggacagg gcctctcaga tgctgacctg ctcggacggc aactgtcacc tgctgaagac cattcacgta gccagccact ctcgcaaggc ctggccagtg tttgagcata acatactgac ccgctgttcc ttgcatttgg gtaacaggag gggggtgttc ctaccttacc aatgcaattt gagtcacact aagatattgc ttgagcccga gagcatgtcc aaggtgaacc tgaacggggt gtttgacatg accatgaaga tctggaaggt gctgaggtac gatgagaccc gcaccaggtg cagaccctgc gagtgtggcg gtaaacatat taggaaccag cctgtgatgc tggatgtgac cgaggagctg aggcccgatc acttggtgct ggcctgcacc cgcgctgagt ttggctctag cgatgaagat acagattgaatggagcgaaga aacccatctg agcgggg a gt acctgctgga ttttctggcc atgcatctgt ggagagcggt tgtgagacac aagaatcgcc tgctactgtt gtcttccgtc cgcccggcga taataccgac ggaggagcag cagcagcagc aggaggaagc caggcggcgg cggcaggagc agagcccatg gaacccgaga gccggcctgg accctcggga atgaatgttg tacaggtggc tgaactgtat ccagaactga gacgcatttt gacaattaca gaggatgggc aggggctaaa gggggtaaag agggagcggg gggcttgtga ggctacagag gaggctagga atctagcttt tagcttaatg accagacacc gtcctgagtg tattactttt caacagatca aggataattg cgctaatgag cttgatctgc tggcgcagaa gtattccata gagcagctga ccacttactg gctgcagcca ggggatgatt ttgaggaggc tattagggta tatgcaaagg tggcacttag gccagattgc aagtacaaga tcagcaaact tgtaaatatc aggaattgtt gctacatttc tgggaacggg gccgaggtgg agatagatac ggaggatagg gtggccttta gatgtagcat gataaatatg tggccggggg tgcttggcat ggacggggtg gttattatga atgtaaggtt tactggcccc aattttagcg gtacggtttt cctggccaat accaacctta tcctacacgg tgt t agcttc tatgggttta acaatacctg tgtggaagcc tggaccgatg taagggttcg gggctgtgcc ttttactgct gctggaaggg ggtggtgtgt cgccccaaaa gcagggcttc aatt aagaaa tgcctctttg aaaggtgtac cttgggtatc ctgtctgagg gtaactccag ggtgcgccac aatgtggcct ccgactgtgg ttgcttcatg ctagtgaaaa gcgtggctgt gattaagcat aacatggtat gtggcaactg cgaggacagg gcctctcaga tgctgacctg ctcggacggc aactgtcacc tgctgaagac cattcacgta gccagccact ctcgcaaggc ctggccagtg tttgagcata acatactgac ccgctgttcc ttgcatttgg gtaacaggag gggggtgttc ctaccttacc aatgcaattt gagtcacact aagatattgc ttgagcccga gagcatgtcc aaggtgaacc tgaacggggt gtttgacatg accatgaaga tctggaaggt gctgaggtac gatgagaccc gcaccaggtg cagaccctgc gagtgtggcg gtaaacatat taggaaccag cctgtgatgc tggatgtgac cgaggagctg aggcccgatc acttggtgct ggcctgcacc cgcgctgagt ttggctctag cgatgaagat acagattga

본 발명자들은 기출원된 골수 유래 인간 MSC로부터 인간 MSC-CAR-E1B55K 세포주 확립하였으며(특허문헌 1), 바이러스 생산 증가를 확인하였으나, 계대 증식이 용이하지 않았으며 passage 경과함에 따라 세포주 상태 나빠짐을 확인하였으며, 이로 인해 동물실험 및 master cell banking이 불가능함을 확인하고 그 원인 파악하는데 많은 시간 소요하였다. 특히 E1B55K의 새로운 기능을 확인하였다. 이는 E1B55K의 바이러스 증식 증가 유도 기능 외에도 세포주의 생존능 저하를 동시에 유도한다는 사실이다.The present inventors established a human MSC-CAR-E1B55K cell line from bone marrow-derived human MSC previously applied (Patent Document 1), and confirmed an increase in virus production, but it was confirmed that passage proliferation was not easy and the cell line condition deteriorated as passage passed. , it took a lot of time to confirm that animal testing and master cell banking were impossible and to understand the cause. In particular, the new function of E1B55K was confirmed. This is the fact that E1B55K induces a decrease in the viability of the cell line in addition to the increase in viral proliferation induction function.

MSC 세포주 대량 생산을 위해 불가피하게 도입된 TERT 유전자에 의한 종양원성 가능성 증가는 E1B55K가 바이러스 복제 증가 유도뿐만 아니라 MSC 세포의 전반적인 생존능 감소를 유도하는 것을 처음으로 규명함으로써 해결방안을 마련할 수 있었다. 즉, E1B55K 유전자의 발현시점을 시간차 유도하여 MSC의 계대 증식을 가능하게 하여 cell banking을 통한 대량 생산 가능하게 함과 동시에 MSC의 종양원성(tumorigenesis)을 원천적으로 차단시킬 수 있었다.The increase in the oncogenic potential caused by the TERT gene, which was inevitably introduced for mass production of MSC cell lines, could be solved by identifying for the first time that E1B55K not only induces an increase in viral replication but also induces a decrease in the overall viability of MSC cells. That is, by inducing the time difference in the expression time of the E1B55K gene, it was possible to serially propagate MSCs, enable mass production through cell banking, and at the same time fundamentally block the tumorigenesis of MSCs.

E1B55K 유전자의 발현시점을 시간차 유도하기 위하여, 즉 중간엽 줄기세포의 체내 도입 후 발현되도록 하기 위하여 실시예에서는 Tet-on system을 적용하였으나, 이 외에 시간차 유도 시스템이라면 모두 가능하다. 또한, 발현 유도 물질은 독시사이클린 또는 테트라사이클린 등이 바람직하다.In order to induce a time difference in the expression time of the E1B55K gene, that is, to induce expression after the introduction of the mesenchymal stem cells into the body, the Tet-on system was applied in the Example, but any other time difference induction system is possible. In addition, the expression inducer is preferably doxycycline or tetracycline.

본 발명에서 MSC-TERT-tetoneE1B55K 세포주를 확립하였으며, 시간차를 통해 원하는 시점에 E1B55K를 발현시켜 (종양 살상) 바이러스 대량 생산 및 MSC의 종양원성(tumorigenesis)을 원천적으로 차단시켰다.In the present invention, the MSC-TERT-tetoneE1B55K cell line was established, and E1B55K was expressed at a desired time through time difference (oncolytic) to fundamentally block virus mass production and MSC tumorigenesis.

또한, 본 발명은 GRP78(Glucose regulated protein 78) 유전자 및 E1B55K 유전자를 포함하며, 상기 E1B55K 유전자는 발현유도물질에 의해 발현되는 것인 종양 살상 바이러스 전달용 중간엽 줄기세포를 포함한다.In addition, the present invention includes a GRP78 (glucose regulated protein 78) gene and an E1B55K gene, wherein the E1B55K gene is expressed by an expression inducer and mesenchymal stem cells for oncolytic virus delivery.

본 발명에서 MSC-TERT-tetoneE1B55K-GRP78 세포주를 확립하였으며, 바이러스 전달체 및 바이러스 증식을 위한 중간엽 줄기세포의 종양 타겟팅 향상 및 바이러스 대량 생산을 가능하도록 바이러스 생산과 방출 시기 제어 가능함을 확인하였다.MSC-TERT-tetoneE1B55K-GRP78 in the present invention A cell line was established, and it was confirmed that the virus production and release timing could be controlled to improve the tumor targeting of mesenchymal stem cells for virus delivery and virus propagation and to enable mass production of viruses.

본원에서 사용된 중간엽 줄기세포주는 인간 유래인 것이 바람직하다. 상기 중간엽 줄기세포주는 골수, 재대혈 또는 지방 유래인 것이 바람직하다.The mesenchymal stem cell line used herein is preferably human-derived. The mesenchymal stem cell line is preferably derived from bone marrow, cord blood or adipose.

본원에서 사용된 종양 살상 바이러스는 종양 살상 아데노바이러스, 종양 살상 아데노-관련 바이러스(Adeno-associated viruses, AAV), 종양 살상 레트로바이러스, 종양 살상 렌티바이러스, 종양 살상 헤르페스 심플렉스 바이러스 또는 종양 살상 백시니아 바이러스일 수 있다. Oncolytic virus as used herein is an oncolytic adenovirus, an oncolytic adeno-associated virus (AAV), an oncolytic retrovirus, an oncolytic lentivirus, an oncolytic herpes simplex virus or an oncolytic vaccinia virus. can be

또한, 상기 종양 살상 아데노바이러스는 본 발명자들에 의해 개발된 국내 특허 출원 제 2016-0166171호에 기재된 종양 살상 아데노바이러스일 수 있다.In addition, the oncolytic adenovirus may be an oncolytic adenovirus described in Korean Patent Application No. 2016-0166171 developed by the present inventors.

본 발명은 또한, 상기 종양 살상 바이러스 전달용 중간엽 줄기세포 및 종양 살상 바이러스를 포함하는 항암 유전자 전달용 조성물을 포함한다.The present invention also includes a composition for anticancer gene delivery comprising the mesenchymal stem cells for delivery of the oncolytic virus and the oncolytic virus.

본 발명의 유전자 전달용 조성물은 전신성 투여용 일 수 있다. The composition for gene transfer of the present invention may be for systemic administration.

본 발명의 바이러스를 탑재한 줄기세포(Ad-MSC)의 경우 암 특이적인 특성 외에, 면역 반응이 낮거나 없어, 전신투여가 가능하고, 종양세포로 타겟성이 우수하며 독성을 유발하지 않는 효과가 있어, 유전자 전달 효율을 현저하게 높일 수 있다.In the case of stem cells (Ad-MSC) loaded with the virus of the present invention, in addition to cancer-specific characteristics, it has a low or no immune response, so systemic administration is possible, and it has excellent targeting to tumor cells and has an effect that does not induce toxicity. Therefore, the gene transfer efficiency can be significantly increased.

상기 중간엽 줄기세포는 골수, 재대혈, 지방 등에서 분리할 수 있고, 환자 자신 또는 혈액은행의 데이터베이스를 이용하여 동종의 중간엽 줄기세포를 사용할 수 있다. 따라서, 본 발명의 아데노바이러스 탑재 줄기세포를 유전자 전달체로 이용하는 경우 자가 치료뿐 아니라 동종의 치료도 가능한 바, 유전자 치료의 단가를 더욱 낮출 수 있다.The mesenchymal stem cells can be isolated from bone marrow, cord blood, adipose, and the like, and allogeneic mesenchymal stem cells can be used using the patient's own database or a blood bank database. Therefore, when the adenovirus-loaded stem cell of the present invention is used as a gene delivery agent, not only self-treatment but also the same type of treatment is possible, thereby further lowering the unit cost of gene therapy.

본 발명의 유전자를 포함하는 아데노바이러스를 중간엽 줄기세포 내로 도입하는 방법은 당업계에 공지된 다양한 방법을 통해 실시될 수 있다. 구체적으로, 상기 유전자 도입은 당업계에 공지된 바이러스 감염 방법에 따라 수행될 수 있다.The method of introducing the adenovirus containing the gene of the present invention into mesenchymal stem cells can be carried out through various methods known in the art. Specifically, the gene introduction may be performed according to a viral infection method known in the art.

본 발명에서 사용된 용어 "항암 약제학적 조성물"은 "암 치료에서의 사용을 위한 의약 조성물"을 의미한다.As used herein, the term "anticancer pharmaceutical composition" means "a pharmaceutical composition for use in cancer treatment".

본 발명의 항암 약제학적 조성물에 유효성분으로 포함되는 중간엽 줄기세포는 상술한 본 발명의 중간엽 줄기세포와 동일한 것이므로, 중간엽 줄기세포에 대한 상세한 설명은 본 발명의 조성물에도 그대로 적용된다. 따라서, 본 명세서의 불필요한 반복 기재에 의한 과도한 복잡성을 피하기 위하여 공통 사항은 그 기재를 생략한다.Since the mesenchymal stem cells included as an active ingredient in the anticancer pharmaceutical composition of the present invention are the same as the mesenchymal stem cells of the present invention described above, the detailed description of the mesenchymal stem cells is also applied to the composition of the present invention as it is. Therefore, in order to avoid excessive complexity due to unnecessary repetition of descriptions of the present specification, descriptions of common matters are omitted.

본 발명의 조성물에 포함되는 종양 살상 아데노바이러스는 상술한 바와 같이, 다양한 종양 세포에 대하여 살상 효능을 나타내므로, 본 발명의 약제학적 조성물은 위암, 폐암, 유방암, 난소암, 간암, 기관지암, 비인두암, 후두암, 췌장암, 담도암, 방광암, 대장암, 결장암, 자궁경부암, 뇌암, 전립선암, 골암, 두경부암, 피부암, 신장암, 배수성암(polyploid carcinoma), 갑상선암, 부갑상선암 또는 요관암 등 암 치료에 이용될 수 있다. 본 명세서에서 용어 "치료"는 (i) 종양 세포 형성의 예방; (ii) 종양 세포의 제거에 따른 종양과 관련된 질병 또는 질환의 억제; 및 (iii) 종양 세포의 제거에 따른 종양과 관련된 질병 또는 질환의 경감을 의미한다. 따라서, 본 명세서에서 용어 "치료학적 유효량"은 상기한 약리학적 효과를 달성하는 데 충분한 양을 의미한다.As described above, the oncolytic adenovirus included in the composition of the present invention exhibits killing efficacy against various tumor cells, so the pharmaceutical composition of the present invention is gastric cancer, lung cancer, breast cancer, ovarian cancer, liver cancer, bronchial cancer, nasopharyngeal cancer Cancers such as head cancer, laryngeal cancer, pancreatic cancer, biliary tract cancer, bladder cancer, colorectal cancer, colon cancer, cervical cancer, brain cancer, prostate cancer, bone cancer, head and neck cancer, skin cancer, kidney cancer, polyploid carcinoma, thyroid cancer, parathyroid cancer or ureter cancer can be used for treatment. As used herein, the term “treatment” refers to (i) prevention of tumor cell formation; (ii) inhibition of a disease or disorder associated with a tumor upon removal of tumor cells; and (iii) alleviation of a disease or condition associated with the tumor upon removal of the tumor cells. Accordingly, as used herein, the term “therapeutically effective amount” refers to an amount sufficient to achieve the aforementioned pharmacological effect.

본 발명의 조성물에 포함되는 약제학적으로 허용되는 담체는 제제 시에 통상적으로 이용되는 것으로서, 락토스, 덱스트로스, 수크로스, 솔비톨, 만니톨, 전분, 아카시아 고무, 인산 칼슘, 알기네이트, 젤라틴, 규산 칼슘, 미세결정성 셀룰로스, 폴리비닐피롤리돈, 셀룰로스, 물, 시럽, 메틸 셀룰로스, 메틸히드록시벤조에이트, 프로필히드록시벤조에이트, 활석, 스테아르산 마그네슘 및 미네랄 오일 등을 포함하나, 이에 한정되는 것은 아니다.Pharmaceutically acceptable carriers included in the composition of the present invention are commonly used in formulation, and include lactose, dextrose, sucrose, sorbitol, mannitol, starch, acacia gum, calcium phosphate, alginate, gelatin, calcium silicate. , microcrystalline cellulose, polyvinylpyrrolidone, cellulose, water, syrup, methyl cellulose, methylhydroxybenzoate, propylhydroxybenzoate, talc, magnesium stearate, and mineral oil, and the like. not.

본 발명의 약제학적 조성물은 상기 성분들 이외에 윤활제, 습윤제, 감미제, 향미제, 유화제, 현탁제, 보존제 등을 추가로 포함할 수 있다.The pharmaceutical composition of the present invention may further include a lubricant, a wetting agent, a sweetening agent, a flavoring agent, an emulsifying agent, a suspending agent, a preservative, and the like, in addition to the above components.

본 발명의 약제학적 조성물은 비경구 투여가 바람직하고, 예컨대 정맥내 투여, 복강내 투여, 근육내 투여, 피하 투여 또는 국부 투여를 이용하여 투여할 수 있다. 난소암에서 복강 내로 투여하는 경우 및 간암에서 문맥으로 투여하는 경우에는 주입 방법으로 투여할 수 있고, 간암, 흑색종 및 유방암의 경우에는 종양 매스에 직접 주사하여 투여할 수 있으며, 결장암의 경우에는 관장으로 직접 주사하여 투여할 수 있고, 방광암의 경우에는 카테터 내로 직접 주사하여 투여할 수 있다.The pharmaceutical composition of the present invention is preferably administered parenterally, for example, can be administered using intravenous administration, intraperitoneal administration, intramuscular administration, subcutaneous administration or local administration. In the case of intraperitoneal administration in ovarian cancer and portal vein administration in liver cancer, it may be administered by an injection method. It can be administered by direct injection, and in the case of bladder cancer, it can be administered by direct injection into the catheter.

본 발명의 약제학적 조성물의 적합한 투여량은 제제화 방법, 투여 방식, 환자의 연령, 체중, 성, 질병 증상의 정도, 음식, 투여 시간, 투여 경로, 배설 속도 및 반응 감응성과 같은 요인들에 의해 다양하며, 보통으로 숙련된 의사는 목적하는 치료에 효과적인 투여량을 용이하게 결정 및 처방할 수 있다. 일반적으로, 본 발명의 약제학적 조성물은 1 × 105 ~ 1 × 1015 pfu/㎖의 종양 살상 바이러스를 포함하며, 통상적으로 1회 주사 시 MSC (1 × 106 세포수 기준) 감염시키는 바이러스의 양은 1 × 107 ~ 1 × 108 pfu이다.A suitable dosage of the pharmaceutical composition of the present invention varies depending on factors such as formulation method, administration mode, age, weight, sex, disease severity, food, administration time, administration route, excretion rate, and reaction sensitivity of the patient. and an ordinary skilled physician can easily determine and prescribe an effective dosage for the desired treatment. In general, the pharmaceutical composition of the present invention contains 1 × 10 5 to 1 × 10 15 pfu/ml of oncolytic virus, and usually contains MSC (based on the number of 1 × 10 6 cells) infecting virus at one injection. The amount is 1 × 10 7 to 1 × 10 8 pfu.

본 발명의 약제학적 조성물은 본 발명이 속하는 기술분야에서 통상의 지식을 가진 자가 용이하게 실시할 수 있는 방법에 따라, 약제학적으로 허용되는 담체 및/또는 부형제를 이용하여 제제화됨으로써 단위 용량 형태로 제조되거나 또는 다용량 용기 내에 내입시켜 제조될 수 있다. 이때 제형은 오일 또는 수성 매질 중의 용액, 현탁액 또는 유화액 형태이거나 엑스제, 분말제, 과립제, 정제 또는 캅셀제 형태일 수도 있으며, 분산제 또는 안정화제를 추가적으로 포함할 수 있다.The pharmaceutical composition of the present invention is prepared in a unit dosage form by being formulated using a pharmaceutically acceptable carrier and/or excipient according to a method that can be easily carried out by a person of ordinary skill in the art to which the present invention pertains. or it may be prepared by incorporation into a multi-dose container. In this case, the formulation may be in the form of a solution, suspension, or emulsion in oil or an aqueous medium, or may be in the form of an extract, powder, granule, tablet or capsule, and may additionally include a dispersant or stabilizer.

본 발명의 약제학적 조성물은 단독의 요법으로 이용될 수 있으나, 다른 통상적인 화학 요법 또는 방사 요법과 함께 이용될 수도 있으며, 이러한 병행 요법을 실시하는 경우에는 보다 효과적으로 암 치료를 할 수 있다. 본 발명의 조성물과 함께 이용될 수 있는 화학 요법제는 젬시타빈(gemcitabine), 소라페닙(sorafenib), 시스플라틴(cisplatin), 카르보플라틴(carboplatin), 프로카르바진(procarbazine), 메클로레타민(mechlorethamine), 시클로포스파미드(cyclophosphamide), 이포스파미드(ifosfamide), 멜팔(melphalan), 클로라부실(chlorambucil), 비술판(bisulfan), 니트로소우레아(nitrosourea), 디악티노마이신(dactinomycin), 다우노루비신(daunorubicin), 독소루비신(doxorubicin), 블레오마이신(bleomycin), 플리코마이신(plicomycin), 미토마이신(mitomycin), 에토포시드(etoposide), 탁목시펜(tamoxifen), 택솔(taxol), 트랜스라티눔(transplatinum), 5-플루오로우라실(5-fluorouracil), 빈크리스틴(vincristin), 빈블라스틴(vinblastin) 및 메토트렉세이트(methotrexate) 등을 포함한다. 본 발명의 조성물과 함께 이용될 수 있는 방사 요법은 X-선 조사 및 γ-선 조사 등이다.The pharmaceutical composition of the present invention may be used as a single therapy, but may also be used in combination with other conventional chemotherapy or radiation therapy, and when such a combination therapy is performed, cancer treatment can be more effective. Chemotherapeutic agents that can be used together with the composition of the present invention include gemcitabine, sorafenib, cisplatin, carboplatin, procarbazine, mechlorethamine ( mechlorethamine, cyclophosphamide, ifosfamide, melphalan, chlorambucil, bisulfan, nitrosourea, diactinomycin, Daunorubicin, doxorubicin, bleomycin, plicomycin, mitomycin, etoposide, tamoxifen, taxol, translatinum, 5-fluorouracil, vincristin, vinblastin, and methotrexate. Radiation therapy that can be used together with the composition of the present invention is X-ray irradiation, γ-ray irradiation, and the like.

본 발명에 따른 중간엽 줄기세포는 위암, 폐암, 유방암, 난소암, 간암, 기관지암, 비인두암, 후두암, 췌장암, 담도암, 방광암, 대장암, 결장암, 자궁경부암, 뇌암, 전립선암, 골암, 두경부암, 피부암, 신장암, 배수성암(polyploid carcinoma), 갑상선암, 부갑상선암 또는 요관암에 대한 항암 효과를 나타낼 수 있다.The mesenchymal stem cells according to the present invention are gastric cancer, lung cancer, breast cancer, ovarian cancer, liver cancer, bronchial cancer, nasopharyngeal cancer, laryngeal cancer, pancreatic cancer, biliary tract cancer, bladder cancer, colorectal cancer, colon cancer, cervical cancer, brain cancer, prostate cancer, bone cancer, It can show anticancer effect on head and neck cancer, skin cancer, kidney cancer, polyploid carcinoma, thyroid cancer, parathyroid cancer or ureter cancer.

또한, 본 발명은 상기 중간엽 줄기세포 및 종양 살상 바이러스를 포함하는 바이러스/줄기세포 복합체를 포함하는 암 진단용 조성물을 포함할 수 있다.In addition, the present invention may include a composition for diagnosing cancer including the virus/stem cell complex including the mesenchymal stem cells and the oncolytic virus.

본 명세서에서 사용된 용어 "진단"은 병태 생리의 존재 또는 특징을 확인하는 것을 의미한다. 본 발명에서의 진단은 암의 발병 여부 및 경과를 확인하는 것이다. As used herein, the term “diagnosis” refers to ascertaining the presence or characteristics of pathophysiology. Diagnosis in the present invention is to confirm the onset and progress of cancer.

상기 바이러스/줄기세포 복합체는 바이러스가 감염 또는 탑재된 줄기세포를 의미한다.The virus/stem cell complex refers to a stem cell infected with or loaded with a virus.

상기 바이러스/줄기세포 복합체는 영상을 통하여 암을 진단하기 위하여 발광물질, 형광체 또는 동위원소와 결합할 수 있다.The virus/stem cell complex may bind to a luminescent material, a fluorescent substance, or an isotope to diagnose cancer through imaging.

상기 발광 물질은 발광을 발생시키는 모든 물질을 말한다.The light-emitting material refers to any material that emits light.

본 발명의 실시예에서는 MSC에 루시퍼라제를 발현하는 아데노바이러스를 감염시킨 후 마우스의 복강에 루시페린을 투여하여 발광을 영상으로 촬영하여 한 것을 확인하였다.In an example of the present invention, it was confirmed that MSCs were infected with an adenovirus expressing luciferase, and then luciferin was administered to the abdominal cavity of the mouse to capture the luminescence as an image.

상기 형광체는 상기 NRP1에 특이적으로 결합하는 펩타이드와 결합할 수 있는 형광체, 형광 단백질 또는 기타 영상용 물질이 바람직하나 이에 한정되지 않는다.The phosphor is preferably a phosphor, a fluorescent protein, or other imaging material capable of binding to the peptide that specifically binds to NRP1, but is not limited thereto.

상기 형광체는 플루오레신(fluorescein), 보디피(BODYPY), 테트라메틸로드아민(Tertramethylrhodamine), 알렉사(Alexa), 시아닌(Cyanine), 알로피코시아닌(allopicocyanine) 또는 이들의 유도체가 바람직하나 이에 한정되지 않는다.The phosphor is preferably fluorescein, BODYPY, tetramethylrhodamine, Alexa, cyanine, allopicocyanine, or a derivative thereof, but limited thereto doesn't happen

형광 단백질은 Dronpa 단백질, 형광 발색 유전자(EGFP), 적색 형광 프로테인(red fluorescent protein, DsRFP), 근적외선 형광을 나타내는 시아닌 형광체인 Cy5.5 또는 기타 형광 단백질이 바람직하나 이에 한정되지 않는다. 기타 영상용 물질은 산화철, 방사성 동위원소 등이 바람직하나 이에 한정되지 않으며, MR, PET과 같은 영상 장비에 응용될 수 있다.The fluorescent protein is preferably, but not limited to, Dronpa protein, a fluorescent gene (EGFP), a red fluorescent protein (DsRFP), Cy5.5, which is a cyanine fluorescent substance exhibiting near-infrared fluorescence, or other fluorescent proteins. Other imaging materials are preferably iron oxide, radioactive isotopes, etc., but are not limited thereto, and may be applied to imaging equipment such as MR and PET.

본 발명은 또한, 치료상의 유효량의, 상기 중간엽 줄기세포 및 종양 살상 바이러스를 포함하는 약제학적 조성물을 대상체에 투여하는 것을 포함하는 암 치료 방법을 포함한다.The present invention also includes a method of treating cancer comprising administering to a subject a therapeutically effective amount of a pharmaceutical composition comprising said mesenchymal stem cells and an oncolytic virus.

상기 암 치료 방법과 관련하여 기술한 모든 내용이 상술한 본 발명의 중간엽 줄기세포 및 이를 포함하는 조성물에 그대로 적용 또는 준용될 수 있다.All contents described in relation to the cancer treatment method can be applied or applied mutatis mutandis to the mesenchymal stem cells of the present invention and the composition comprising the same as described above.

상기 암은 구체적으로 위암, 폐암, 유방암, 난소암, 간암, 기관지암, 비인두암, 후두암, 췌장암, 담도암, 방광암, 대장암, 결장암, 자궁경부암, 뇌암, 전립선암, 골암, 두경부암, 피부암, 신장암, 배수성암(polyploid carcinoma), 갑상선암, 부갑상선암 또는 요관암일 수 있으나, 이에 한정되지 않는다.The cancer is specifically stomach cancer, lung cancer, breast cancer, ovarian cancer, liver cancer, bronchial cancer, nasopharyngeal cancer, laryngeal cancer, pancreatic cancer, biliary tract cancer, bladder cancer, colorectal cancer, colon cancer, cervical cancer, brain cancer, prostate cancer, bone cancer, head and neck cancer, skin cancer , kidney cancer, polyploid carcinoma, thyroid cancer, parathyroid cancer or ureter cancer.

여기에서 사용된 용어 "대상체"는 치료, 관찰 또는 실험의 대상인 포유동물을 말하며, 바람직하게는 인간을 말한다.As used herein, the term “subject” refers to a mammal that is the subject of treatment, observation or experimentation, and preferably refers to a human.

여기에서 사용된 용어 "치료상 유효량"은 연구자, 수의사, 의사 또는 기타 임상의에 의해 생각되는 조직계, 동물 또는 인간에서 생물학적 또는 의학적 반응을 유도하는 유효성분 또는 약학적 조성물의 양을 의미하는 것으로, 이는 치료되는 질환 또는 장애의 증상의 완화를 유도하는 양을 포함한다. 본 발명의 유효 성분에 대한 치료상 유효량 및 투여횟수는 원하는 효과에 따라 변화될 것임은 당업자에게 자명하다. 그러므로 투여될 최적의 투여량은 당업자에 의해 쉽게 결정될 수 있으며, 질환의 종류, 질환의 중증도, 조성물에 함유된 유효성분 및 다른 성분의 함량, 제형의 종류, 환자의 체중, 연령, 성별, 건강상태, 식이, 투여시간, 투여방법, 배설율 등에 따라 그 범위가 다양하다. 본 발명의 치료방법에 있어서, 1 × 105 ~ 1 × 1015 pfu/㎖의 종양 살상 바이러스를 포함하며, 통상적으로 1회 주사 시 MSC (1 × 106 세포수 기준) 감염시키는 바이러스의 양은 1 × 107 ~ 1 × 108 pfu이다.As used herein, the term "therapeutically effective amount" refers to an amount of an active ingredient or pharmaceutical composition that induces a biological or medical response in a tissue system, animal or human as thought by a researcher, veterinarian, physician or other clinician, This includes amounts that result in amelioration of the symptoms of the disease or disorder being treated. It is apparent to those skilled in the art that the therapeutically effective amount and frequency of administration for the active ingredient of the present invention will vary depending on the desired effect. Therefore, the optimal dosage to be administered can be easily determined by those skilled in the art, and the type of disease, the severity of the disease, the content of active ingredients and other components contained in the composition, the type of formulation, the patient's weight, age, sex, and health condition , the range varies depending on the diet, administration time, administration method, excretion rate, etc. In the treatment method of the present invention, 1 × 10 5 to 1 × 10 15 pfu/ml of oncolytic virus is included, and the amount of virus that infects MSCs (based on the number of 1 × 10 6 cells) is usually 1 × 10 7 to 1 × 10 8 pfu.

본 발명의 치료방법에서 본 발명의 약제학적 조성물은 목적하는 방법에 따라 경구 투여하거나 비경구 투여(예를 들어, 정맥 내, 피하, 복강 내 또는 국소에 적용)할 수 있다.In the treatment method of the present invention, the pharmaceutical composition of the present invention may be administered orally or parenterally (eg, intravenously, subcutaneously, intraperitoneally or locally applied) according to a desired method.

암 환자 사망율의 대다수는 전이성 종양에 기인하므로 투여된 바이러스 대비 종양으로의 이동성 및 충분한 양의 종양 살상 바이러스가 종양에 전달되도록 기존의 MSC에 대한 아데노바이러스의 복제율 저하를 획기적으로 개선하였으며, 동시에 종양타겟팅이 향상된 MSC를 개발하였다.Since the majority of cancer patient mortality is due to metastatic tumors, the reduction in the replication rate of adenoviruses for existing MSCs was dramatically improved so that the migration to the tumor compared to the administered virus and a sufficient amount of the oncolytic virus were delivered to the tumor, while at the same time tumor targeting This improved MSC was developed.

본 발명에 따른 MSC은 종양타겟팅의 현저한 개선 및 동시에 MSC를 기존 바이러스 생산 세포주에 맞먹는 효율로 바이러스의 생산 공장으로 이용함으로써 IVP/VP (infectious virus particle/virus particle)의 현저한 증가에 따른 부작용은 최소화되면서 안전성 및 항암 효능의 획기적 개선이 가능하였다. 즉, 바이러스 기반 항암제의 가장 큰 난제인 종양원성, 종양 향성, 종양 이동능 및 바이러스의 적절한 시점에 생상/방출 조절 등을 해결하여, 종양살상 바이러스 탑재 MSC의 유효성 최대화 및 독성 최소화를 동시에 달성할 수 있다. The MSC according to the present invention significantly improves tumor targeting and at the same time uses the MSC as a virus production plant with an efficiency comparable to that of an existing virus-producing cell line. It was possible to dramatically improve safety and anticancer efficacy. In other words, it is possible to simultaneously maximize the effectiveness and minimize toxicity of oncolytic virus-loaded MSCs by solving the biggest challenges of virus-based anticancer drugs, such as tumorigenicity, tumor tropism, tumor mobility, and virus production/release control at an appropriate time. there is.

도 1은 인간 지방(human adipose) MSC-TERT의 TERT 발현을 웨스턴 블랏팅으로 확인한 것이다.
도 2는 인간 지방 MSC-TERT의 계대 증식이 passage 30에서도 유효한지를 웨스턴 블랏팅으로 확인한 것이다.
도 3은 인간 지방 MSC-TERT의 아데노바이러스 감염능을 형광현미경으로 확인한 것이다.
도 4는 인간골수와 지방 MSC에서 E1B55K 발현 유도 시 p53 축적 및 생존관련신호 감소가 일어나는 것을 웨스턴 블랏팅으로 확인한 것이다.
도 5는 Tet-One 유도 발현 시스템으로 독시사이클린 존재 하에 E1B55K의 발현으로 p53 프로모터 활성증가를 발광 강도로 확인한 것이다.
도 6은 E1B55K에 의한 p53 프로모터 활성증가가 E4orf6에 의해 저하되는 것을 발광 강도로 확인한 것이다.
도 7은 아데노바이러스 백본인 dl324-BstBI에서 E4orf6 유전자를 PCR로 증폭하여 pFlag-CMV2 벡터로 옮긴 후 서열 분석하여 100% 일치함을 확인한 것이다.
도 8은 아데노바이러스 셔틀벡터인 pCA14에 E1B55K 유전자를 삽입한 것을 DNA 전기영동으로 확인한 것이다.
도 9는 pCA14-E1B55K의 E1B55K 유전자 서열을 확인한 것이다.
도 10a는 E1B55K에 대한 다클론 항체(polyclonal antibody)에 의한 E1B55K 검출에 이상이 없음을 확인한 것이다.
도 10b는 정제한 E1B55K 발현하는 복제 불능 바이러스의 MOI별 검출 결과 정상적인 발현이 이루어지고 있음을 확인한 것이다.
도 11은 E1B55K 발현하는 플라스미드를 MSC-TERT에 트랜스펙션 도입시키고 종양 살상 아데노바이러스 감염 시 바이러스 생산이 향상되고 있음을 바이러스 titration으로 확인한 것이다.
도 12는 E1B55K 발현하는 복제불능 바이러스를 MSC-TERT에 MOI별 감염 후 종양 살상 아데노바이러스 추가 감염 시 바이러스 생산이 MOI 증가에 따라 향상되고 있음을 바이러스 titration으로 확인한 것이다.
도 13은 Tet-One 유도 발현 시스템의 프로토콜을 나타낸 것이다.
도 14는 pRetro-x-tetone-puro-E1B55K 제작 시 PCR 조건을 나타낸 것이다.
도 15는 In-fusion 방식의 외부 유전자 도입 방식으로 E1B55K가 pRetro-x-Tetone에 제대로 삽입된 construct 플라스미드를 확인한 것이다.
도 16은 제작에 사용된 pRetro-x-Tetone-puro-E1B55K 벡터의 개열지도이다
도 17은 pRetro-x-Tetone에 삽입된 E1B55K 플라스미드를 서열 분석하여 최종적으로 도입을 확인한 것이다.
도 18은 pRetro-x-Tetone에 삽입된 유전자인 E1B55K가 독시사이클린에 의해 단백질로 발현 유도되는지를 확인한 것이다.
도 19는 독시사이클린 처리 시 독시사이클린 양에 따른 pRetro-x-tetone-puro-E1B55K에서 E1B55K의 단백질 발현을 확인한 것이다
도 20은 인간 지방 MSC-TERT 에 pRetro-Tetone-E1B55K 트랜스펙션 후 종양 살상 아데노바이러스 감염 후 독시사이클린 처리 유무에 따른 바이러스 생산을 비교한 것이다
도 21은 MSC-TERT로부터 MSC-TERT-tetoneE1B55K 세포주 확립한 웨스턴 블랏팅 결과이다.
도 22는 MSC-TERT-tetoneE1B55K 세포주로부터 독시사이클린 (2.5 μg/ml) 존재한 조건에서 p53의 축적을 웨스턴 블랏으로 확인한 결과이다
도 23은 MSC-TERT-tetoneE1B55K 세포주의 종양원성 제거 가능성을 확인한 것이다.
도 24a는 GRP78의 증가에 의해 MSC homing의 각 단계에 작용하는 인자들의 발현이 모두 증가하고 있음을 확인한 것이다.
도 24b는 GRP78 발현이 확실히 되고 있음을 확인하기 위해 인간 MSC-TERT 에 pcDNA3.1-GRP78 도입하여 GRP78의 mRNA 발현 증가를 확인한 것이다.
도 25는 pcDNA3.1-hygro 벡터에 GRP78 유전자 삽입 여부를 확인한 결과이다[C: pcDNA3.1-hygro].
도 26은 pcDNA3.1-GRP78 클론으로부터 얻은 플라스미드를 간암 세포주에 트랜스펙션 후 웨스턴 블랏팅으로 GRP78의 단백질 발현 증가를 확인하여 유전자 도입을 검증한 것이다.
도 27은 pcDNA3.1-GRP78 클론으로부터 얻은 플라스미드로부터 도입된 GRP78 유전자의 염기서열을 분석한 결과이다.
도 28은 LNCX 벡터의 제한효소 인식 부위를 증가시킨 LNCXneo 벡터의 개열지도를 나타낸 것이다.
도 29는 LNCXneo에 GRP78 유전자가 삽입된 플라스미드 클론들을 제한효소절단으로 스크리닝한 결과이다.
도 30은 MSC-TERT 세포주로부터 GRP78 유전자를 발현하는 레트로바이러스를 도입시켜 GRP78을 발현하는 클론들을 스크리닝한 결과이다.
도 31은 MSC-TERT-GRP78 도달 부위가 매우 빠른 시간 내에 다른 장기로의 흡착 없이 종양조직 부위로 모여든 것을 명확하게 확인한 결과이다.
도 32는 유전자 이입 완료된 최종 타입의 MSC-TERT-tetoneE1B55K-GRP78의 종양 타겟팅 검증 (종양으로의 신속 정확)을 폐암(a), 간암(b), 췌장암(c) 세포주에서 확인한 결과이다.
도 33은 최종 타입 MSC-TERT-tetoneE1B55K-GRP78의 종양 내 침투 (infiltration) 향상을 주사 24시간(a), 48시간(b) 및 72시간(c) 후 확인한 결과이다.
도 34는 최종 타입 MSC-TERT-tetoneE1B55K-GRP78에 종양 살상 바이러스가 감염되었을 때 독시사이클린 존재 하에 종양 조직 내 아데노바이러스 관련 단백질의 발현을 확인한 것이다.
도 35는 최종 타입 MSC-TERT-tetoneE1B55K-GRP78 세포주 클론 21, 24, 25, 26번 세포주를 확립한 결과이다.
도 36은 최종 클론 21번에서 독시사이클린에 의한 E1B55K 유도가 매우 낮은 농도에서도 누출이 전혀 없이 효과적으로 충분히 발현 유도되고 있음을 확인한 결과이다.
도 37은 최종 타입 MSC-TERT-tetoneE1B55K-GRP78에 종양 살상 바이러스가 감염되었을 때 독시사이클린 존재 시 또는 E4orf6 발현 시 에 따른 바이러스 생산 양을 나타낸 것이다.
도 38은 MSC-TERT의 계대 증가에 따른 종양 homing 마커 발현을 확인한 것이다.
도 39는 MSC-TERT-tetoneE1B55K-GRP78에 감염된 종양 살상 아데노바이러스의 항종양 효과를 마우스의 종양 크기 변화를 그래프로 확인한 것이다.
도 40a는 MSC-TERT-tetoneE1B55K-GRP78에 감염된 종양 살상 아데노바이러스의 항종양 효과를 마우스의 종양을 적출한 후 크기 변화로 확인한 것이다.
도 40b는 MSC-TERT-tetoneE1B55K-GRP78에 감염된 종양 살상 아데노바이러스의 항종양 효과를 마우스의 종양 크기 변화를 마우스 촬영사진으로 확인한 것이다.
도 41은 종양(a) 및 다른 장기로의 바이러스 흡착 비율을 나타낸 것이다[간(b), 폐(c), 비장(d), 신장(e) 및 심장(f)].
1 is a confirmation of TERT expression of human adipose MSC-TERT by Western blotting.
Figure 2 confirms by Western blotting whether the passage growth of human adipose MSC-TERT is effective even at passage 30.
3 is a fluorescence microscope confirming the adenovirus infectivity of human fat MSC-TERT.
Figure 4 confirms by Western blotting that p53 accumulation and a decrease in survival-related signals occur upon induction of E1B55K expression in human bone marrow and adipose MSCs.
5 is a view showing the increase in p53 promoter activity by expression of E1B55K in the presence of doxycycline in the Tet-One induced expression system as a result of luminescence intensity.
6 is a graph confirming that the increase in p53 promoter activity by E1B55K is decreased by E4orf6 by luminescence intensity.
Figure 7 shows that the E4orf6 gene in the adenovirus backbone, d1324-BstBI, was amplified by PCR, transferred to the pFlag-CMV2 vector, and sequenced to confirm 100% agreement.
8 shows the insertion of the E1B55K gene into pCA14, an adenovirus shuttle vector, confirmed by DNA electrophoresis.
Figure 9 confirms the E1B55K gene sequence of pCA14-E1B55K.
10A shows that there is no abnormality in the detection of E1B55K by a polyclonal antibody against E1B55K.
10B shows that the normal expression of the purified E1B55K-expressing replication-incompetent virus was confirmed as a result of detection by MOI.
Figure 11 shows that E1B55K-expressing plasmid was transfected into MSC-TERT, and virus titration confirmed that virus production was improved during oncolytic adenovirus infection.
12 is a virus titration confirming that virus production is improved as the MOI increases when the E1B55K-expressing replication-incompetent virus is infected with MSC-TERT by MOI and then additionally infected with an oncolytic adenovirus.
13 shows the protocol of the Tet-One induced expression system.
Figure 14 shows the PCR conditions when producing pRetro-x-tetone-puro-E1B55K.
15 is a confirmation of the construct plasmid in which E1B55K is properly inserted into pRetro-x-Tetone by the in-fusion method of external gene introduction.
16 is a cleavage map of the pRetro-x-Tetone-puro-E1B55K vector used for construction.
17 is a sequence analysis of the E1B55K plasmid inserted into pRetro-x-Tetone to confirm the final introduction.
FIG. 18 shows whether E1B55K, a gene inserted into pRetro-x-Tetone, is induced as a protein by doxycycline.
19 shows the protein expression of E1B55K in pRetro-x-tetone-puro-E1B55K according to the amount of doxycycline during doxycycline treatment.
20 is a comparison of virus production with and without doxycycline treatment after oncolytic adenovirus infection after pRetro-Tetone-E1B55K transfection in human fat MSC-TERT.
21 is These are the Western blotting results obtained by establishing the MSC-TERT-tetoneE1B55K cell line from MSC-TERT.
22 is the result of confirming the accumulation of p53 in the MSC-TERT-tetoneE1B55K cell line in the presence of doxycycline (2.5 μg/ml) by Western blot.
23 shows the possibility of eliminating tumorigenicity of the MSC-TERT-tetoneE1B55K cell line.
Figure 24a confirms that the expression of all factors acting on each step of MSC homing is increased by the increase of GRP78.
Figure 24b confirms the increase in the mRNA expression of GRP78 by introducing pcDNA3.1-GRP78 into human MSC-TERT to confirm that GRP78 expression is clear.
25 is a result of confirming whether the GRP78 gene is inserted into the pcDNA3.1-hygro vector [C: pcDNA3.1-hygro].
26 is a view illustrating gene introduction by confirming the increase in GRP78 protein expression by Western blotting after transfection of the plasmid obtained from the pcDNA3.1-GRP78 clone into a liver cancer cell line.
27 is a result of analyzing the nucleotide sequence of the GRP78 gene introduced from the plasmid obtained from the pcDNA3.1-GRP78 clone.
28 shows a cleavage map of the LNCXneo vector in which the restriction enzyme recognition site of the LNCX vector is increased.
29 is a result of screening plasmid clones in which the GRP78 gene is inserted into LNCXneo by restriction enzyme digestion.
30 is a result of screening clones expressing GRP78 by introducing a retrovirus expressing the GRP78 gene from the MSC-TERT cell line.
31 is a result of clearly confirming that the MSC-TERT-GRP78 arrival site was gathered into the tumor tissue site within a very short time without adsorption to other organs.
Figure 32 is the result of confirming the tumor targeting validation (quick and accurate to tumor) of the final type of MSC-TERT-tetoneE1B55K-GRP78 introgression completed in lung cancer (a), liver cancer (b), and pancreatic cancer (c) cell lines.
33 is a result confirming the improvement of infiltration in the tumor of the final type MSC-TERT-tetoneE1B55K-GRP78 24 hours (a), 48 hours (b) and 72 hours (c) after injection.
Fig. 34 shows the expression of adenovirus-related proteins in tumor tissues in the presence of doxycycline when the final type MSC-TERT-tetoneE1B55K-GRP78 was infected with an oncolytic virus.
35 is a result of establishing the final type MSC-TERT-tetoneE1B55K-GRP78 cell line clone 21, 24, 25, and 26 cell lines.
36 is a result confirming that in the final clone 21, E1B55K induction by doxycycline is effectively and sufficiently induced without leakage even at a very low concentration.
Figure 37 shows the virus production amount according to the presence of doxycycline or E4orf6 expression when the final type MSC-TERT-tetoneE1B55K-GRP78 is infected with an oncolytic virus.
Figure 38 confirms the expression of tumor homing markers according to the increase in passage of MSC-TERT.
Figure 39 is a graph confirming the change in tumor size of mice on the antitumor effect of the oncolytic adenovirus infected with MSC-TERT-tetoneE1B55K-GRP78.
Figure 40a confirms the anti-tumor effect of the oncolytic adenovirus infected with MSC-TERT-tetoneE1B55K-GRP78 by changing the size of the mouse after excision of the tumor.
Figure 40b shows the antitumor effect of the oncolytic adenovirus infected with MSC-TERT-tetoneE1B55K-GRP78, and the change in the size of the tumor in the mouse was confirmed by photographing the mouse.
Figure 41 shows the rate of virus adsorption to tumors (a) and other organs (liver (b), lung (c), spleen (d), kidney (e) and heart (f)).

이하, 본 발명에 따르는 실시예를 통하여 본 발명을 보다 상세히 설명하나, 본 발명의 범위가 하기 제시된 실시예에 의해 제한되는 것은 아니다. Hereinafter, the present invention will be described in more detail through Examples according to the present invention, but the scope of the present invention is not limited by the Examples presented below.

[실시예][Example]

참조예 1: 인간 종양 살상 아데노바이러스 YSC-02 제작Reference Example 1: Production of human oncolytic adenovirus YSC-02

특허 출원 제 2016-0166171호의 제조예 19에 기재되었듯이 YSC-02를 제작하였다.As described in Preparation Example 19 of Patent Application No. 2016-0166171, YSC-02 was manufactured.

참조예 2: 인간 종양 살상 아데노바이러스 dl324-3484-H1-shHSP27-U6-shTGFβ1 제작Reference Example 2: Production of human oncolytic adenovirus dl324-3484-H1-shHSP27-U6-shTGFβ1

특허 출원 제 2016-0166171호의 제조예 9에 기재되었듯이 dl324-3484-H1-shHSP27-U6-shTGFβ1 를 제작하였다.As described in Preparation Example 9 of Patent Application No. 2016-0166171, dl324-3484-H1-shHSP27-U6-shTGFβ1 was prepared.

제조예 1: MSC 세포주의 대량 생산을 위한Preparation Example 1: For mass production of MSC cell lines TERT 유전자 도입TERT gene introduction

1) 인간 지방(human adipose) MSC-TERT 단일 클론 발현 확인 1) Human adipose MSC-TERT monoclonal expression confirmation

MSC의 짧은 공급과 수명을 극복하는 특정 유전자 발현 유도하기 위하여, TERT 유전자 도입하였다. 인간 MSC의 경우 계대 증식(passage extension)이 용이하지 않다. 이를 극복하기 위하여 세포 증식을 유도하는 TERT (telomerase reverse transcriptase) 유전자 삽입하고 TERT를 높게 발현하는 클론을 선별하였다. In order to induce specific gene expression to overcome the short supply and lifespan of MSCs, the TERT gene was introduced. In the case of human MSC, passage extension is not easy. To overcome this, TERT (telomerase reverse transcriptase) gene that induces cell proliferation was inserted and clones highly expressing TERT were selected.

TERT 유전자 도입방법은 다음과 같다. The TERT gene introduction method is as follows.

플래티눔-A 패키징 세포(Cell Biolabs)에 레트로바이러스 벡터인 pBABE-hygro-hTERT를 Addgene에서 구입하여 1 μg 트랜스펙션하여 얻은 여과시킨 배지를 인간 지방 MSC에 감염시켜 히그로마이신(hygromycin B Gold 200μg/ml)에 저항성을 가지는 세포 클론들을 얻은 후 도 1과 같이 스크리닝하여 선별하였다. MSC 클론 22번을 최종 선별하였으며, 이후 실험에 사용된 인간 지방 MSC-TERT은 22번 클론을 사용하였다. Platinum-A packaging cells (Cell Biolabs) were transfected with 1 μg of a retroviral vector, pBABE-hygro-hTERT, purchased from Addgene, and the filtered medium obtained was infected with human adipose MSC and hygromycin (200 μg of hygromycin B Gold). /ml) after obtaining cell clones resistant to screening and selection as shown in FIG. MSC clone #22 was finally selected, and clone #22 was used for human fat MSC-TERT used in subsequent experiments.

2) 계대 증식 확인2) Confirmation of passage growth

도 2는 인간 MSC의 계대 증식을 확인한 것으로, 30 계대까지 증식되었다. 30 passage까지 확대 계대된 MSC로부터 TERT의 발현 양 증가가 여전히 매우 뚜렷하게 증가된 채 발현되고 있었으며 다른 MSC 관련 주요 마커들의 발현도 wild type 에 비교하여 유지 내지 증가된 결과를 확인하였다. Figure 2 confirms the passage proliferation of human MSC, and it was expanded up to 30 passages. It was confirmed that the expression amount of TERT was still very clearly increased from the MSCs passaged up to 30 passages, and the expression of other MSC-related major markers was maintained or increased compared to the wild type.

3) 아데노바이러스 감염능 확인3) Confirmation of adenovirus infection ability

TERT가 발현되는 MSC 클론 (22번)에 RFP (red fluorescence protein)을 발현하는 복제불능 아데노바이러스를 20 MOI, 100 MOI로 감염시키고 48시간 후에 형광현미경으로 형광 염색된 세포들을 관찰하였다. 대조군인 wild type의 MSC와 비교한 결과, 인간 MSC-TERT 의 감염율이 대조군에 비하여 향상된 것을 확인하였으며, 최소 2배 이상 (20 MOI) 그리고 100 MOI에서 감염율이 90% 이상 충족되었다(도 3). The TERT-expressing MSC clone (No. 22) was infected with replication-defective adenovirus expressing red fluorescence protein (RFP) at 20 MOI and 100 MOI, and after 48 hours, fluorescently stained cells were observed under a fluorescence microscope. As a result of comparison with the control group, wild-type MSC, it was confirmed that the infection rate of human MSC-TERT was improved compared to the control group, and the infection rate was 90% or more satisfied at least twice (20 MOI) and 100 MOI (FIG. 3).

실시예 1: 아데노바이러스 유전자인 E1B55K 의 새로운 기능 확인Example 1: Confirmation of new functions of the adenovirus gene E1B55K

임상용 대량 생산을 위한 세포주로 MSC를 사용하려는 경우 마스터 세포주은행 생산(master cell banking)을 해야 한다. 이를 위해서는 MSC의 passage extension이 무엇보다도 가능해야만 하는 것이 필수적이다. 그러나 한편으로는 extension 유도가 종양원성 가능성 증가에는 기여해서는 절대로 안 된다는 원칙을 또한 유지해야만 한다. 이 두 가지를 동시에 충족시켜야 하는 딜레마를 처음에는 불가능할 것으로 간주되었으나 본 실험실에서 MSC에 CAR와 E1B55K 유전자 도입한 안정한 MSC 세포주 제작하면서 처음으로 해결책을 제시하였다. 기출원된 골수 유래 인간 MSC로부터 인간 MSC-CAR-E1B55K 세포주 확립하였으며 바이러스 생산 증가 확인하였다[특허문헌 1]. 그러나 계대 증식이 용이하지 않았으며 계대 경과함에 따라 세포주 상태 나빠짐을 수 차례 확인하였다. 이로 인해 동물 실험 및 경우 마스터 세포주은행 생산이 불가능함을 확인하고 그 원인을 파악한 결과, E1B55K의 바이러스 증식 증가 유도 기능 외에도 세포주의 생존능 저하를 동시에 유도한다는 사실을 확인하였다 (도 4). 즉. 종양 억제 유전자 및 세포분열 억제 인자로 잘 알려진 p53을 뚜렷하게 축적하며 뿐만 아니라 E1B55K에 의해 세포의 생존과 관련된 인자들 (HSP27, HSP70, Daxx, phospho-p65, NF-κB, c-Met)의 발현이 감소되었음을 확인하였다. If MSCs are to be used as a cell line for mass production for clinical use, master cell banking is required. For this, it is essential that the passage extension of the MSC be possible above all else. On the one hand, however, one must also maintain the principle that extension induction must never contribute to an increase in tumorigenicity. The dilemma of simultaneously satisfying these two problems was initially considered impossible, but a solution was presented for the first time in our laboratory by constructing a stable MSC cell line in which CAR and E1B55K genes were introduced into MSC. A human MSC-CAR-E1B55K cell line was established from the previously applied bone marrow-derived human MSC, and an increase in virus production was confirmed [Patent Document 1]. However, passage growth was not easy, and it was confirmed several times that the cell line condition deteriorated as passage passed. As a result, it was confirmed that the production of the master cell line bank was impossible in animal experiments and cases, and the cause was identified. As a result, it was found that E1B55K not only induces an increase in virus proliferation but also induces a decrease in cell line viability at the same time. confirmed (Fig. 4). In other words. The expression of factors related to cell survival (HSP27, HSP70, Daxx, phospho-p65, NF-κB, c-Met) is inhibited by E1B55K, as well as the marked accumulation of p53, a well-known tumor suppressor gene and mitosis inhibitor. was confirmed to be reduced.

이에 대한 실험 과정은 다음과 같다. The experimental procedure for this is as follows.

먼저 E1B55K를 pcDNA3.1 hygro(+)에 클로닝하였다. E1B55K 유전자가 포함되어 있는 pBSK-3484로부터 E1B55K 유전자를 빼내기 위해 프라이머 각각 BamHI과 NotI을 가지는 프라이머 (forward, 5'-GCGGATCCATGGAGCGAAGAAACCCATCT-3': 서열번호 4, reverse, 5'-GAG CGGCCGCTCAATCTGTATCTTCATCGCT-3': 서열번호 5)로 PCR (initial denaturing: 95℃ 2분 후, denaturing: 95℃ 30초, annealing: 58℃ 30초, extension: 72℃ 2분; 30 cycle) BamHI/NotI 절단 후 미리 BamHI/NotI 절단한 pcDNA3.1 hygro(+)(Invitrogen)에 도입시켜 제작하였다. First, E1B55K was cloned into pcDNA3.1 hygro(+). In order to extract the E1B55K gene from pBSK-3484 containing the E1B55K gene, primers having BamHI and NotI, respectively (forward, 5'-GCGGATCCATGGAGCGAAGAAACCCATCT-3': SEQ ID NO: 4, reverse, 5'-GAG CGGCCGCTCAATCTGTATCTTCATCGCT-3': sequence No. 5) PCR (initial denaturing: 95°C after 2 minutes, denaturing: 95°C 30 seconds, annealing: 58°C 30 seconds, extension: 72°C 2 minutes; 30 cycle) BamHI / NotI digestion after BamHI / NotI digestion in advance It was prepared by introducing pcDNA3.1 hygro(+)(Invitrogen).

E1B55K의 세포주 장기 발현은 세포주의 생존능력을 저하시킨다는 것을 E1B55K를 발현하는 플라스미드를 골수 유래 MSC와 지방 유래 MSC에 트랜스펙션하여 확인하였다. 즉, p53의 축적과 다양한 생존관련 신호들의 저하현상을 관찰하였다. It was confirmed by transfecting the E1B55K-expressing plasmid into bone marrow-derived MSC and adipose-derived MSC that the long-term expression of E1B55K cell line reduces the viability of the cell line. That is, accumulation of p53 and deterioration of various survival-related signals were observed.

E1B55K 발현에 의한 p53의 축적과 세포 생존신호 감소 및 세포사멸 유도가 어떻게 일어나는지를 확인하기 위하여 다음과 같이 가정하였다. 즉, E1B55K의 기존에 잘 알려진 p53 degradation에 의한 세포 생존 유지는 E4orf6 단백질과의 complex를 통하여서만 일어나는 것으로 알려져 있었다. 따라서 MSC 세포에 E1B55K만을 발현 유도하면 E1B55K의 E4orf6에 대한 양적인 비교우위에 의하여 (stoichiometrically) 자유로운 단독의 E1B55K는 p53 전사를 촉진하는 전사활성인자로 작용하여 세포 생존능을 감소시킨다는 가설을 세우고 다음과 같이 실험을 진행하였다. The following assumptions were made to determine how p53 accumulation, cell survival signal reduction, and apoptosis induction by E1B55K expression occurred. In other words, it was known that the maintenance of cell survival by the well-known p53 degradation of E1B55K occurs only through the complex with the E4orf6 protein. Therefore, when MSC cells are induced to express only E1B55K, the quantitative comparative advantage of E1B55K over E4orf6 (stoichiometrically) free E1B55K alone acts as a transcriptional activator that promotes p53 transcription and reduces cell viability. proceeded.

MSC-TERT-tetoneE1B55K 세포주에 p53 프로모터 일정 부분(-344 내지 +12)이 루시퍼라제 코딩 유전자(luciferase coding gene)가 삽입되어 있는 부위 앞쪽으로 위치하도록 제작된 pGL2-p53 프로모터 (pGL2-356bp, Addgene)와 E4orf6 유전자가 서브클로닝된 pFlag-CMV2-E4orf6 또는 대조군으로서 pFlag-CMV2 (Sigma)를 각각 1 μg씩 코트랜스펙션 후 독시사이클린 (1.25 μg/ml 48 h 동안) 유무에 따른 루시퍼라제 활성을 발광 강도로 확인하였다. In MSC-TERT-tetoneE1B55K cell line, a certain part of the p53 promoter (-344 to +12) is located in front of the luciferase coding gene insertion site pGL2-p53 promoter (pGL2-356bp, Addgene) and E4orf6 gene subcloned pFlag-CMV2-E4orf6 or pFlag-CMV2 (Sigma) as a control, 1 μg each, after cotransfection, luciferase activity with or without doxycycline (1.25 μg/ml for 48 h) was measured by luminescence intensity. was confirmed with

이때 사용한 분석방법은 프로메가의 듀얼-루시퍼라제 리포터 어세이 시스템을 사용하였다 (catalog number #E1910, 도 5). The analysis method used at this time was Promega's dual-luciferase reporter assay system (catalog number #E1910, FIG. 5).

독시사이클린 처리에 의하여 MSC-TERT-tetoneE1B55K 세포주에서 발현 유도된 E1B55K에 의하여 p53 프로모터에 직접적으로 혹은 간접적으로 결합하여 전사를 활성화시켜 루시퍼라제 활성에 의한 발광 강도를 4배 이상 증가시켰다(도 5). 반면에 E4orf6 발현이 E1B55K 발현되는 MSC에서 같이 일어나는 경우 발광 강도의 증가는 1.5배를 넘지 못함을 확인하였다. 이러한 결과는 E4orf6는 E1B55K와의 복합체 형성으로 E1B55K 단독의 작용을 간섭함과 동시에 오히려 p53 단백질의 분해를 촉진하는 기존의 알려진 역할을 보다 적극적으로 수행하는 것으로 보인다 (도 6). E1B55K expression induced in MSC-TERT-tetoneE1B55K cell line by doxycycline treatment directly or indirectly binds to the p53 promoter to activate transcription, thereby increasing luminescence intensity by luciferase activity by more than 4 times (FIG. 5). On the other hand, it was confirmed that the increase in luminescence intensity did not exceed 1.5 times when E4orf6 expression occurred in MSC expressing E1B55K. These results indicate that E4orf6 interferes with the action of E1B55K alone by forming a complex with E1B55K, and at the same time rather actively performs the known role of promoting the degradation of p53 protein (FIG. 6).

여기서 E4orf6 (진뱅크 AC_000008; E4 34K라고도 불림) 유전자의 서브클로닝은 아데노바이러스 백본인 dl324-BstBI으로부터 pFlag-CMV2 벡터로 E4orf6 유전자를 옮기는 것을 진행하였다. 이를 위해 E4orf6 PCR용 프라이머 (HindIII를 포함하는 forward 5'- GTACAAGCTTATGACTAC GTCCGGCGTTCC-3': 서열번호 6 및 XbaI을 포함하는 reverse 5'- CACCTCTAGACTACA TGGGGGTAGAGTCAT-3': 서열번호 7)를 사용하여 dl324-BstBI에서 PCR(initial denaturing: 95℃ 2분 후, denaturing : 95℃ 30초, annealing : 58℃ 30초, extension : 72℃ 1분 30초; 30 cycle) 로 E4orf6 코딩 유전자 부위를 증폭한 후 HindIII/XbaI 로 double digestion하고, HindIII와 XbaI로 절단시킨 pFlag-CMV2로 연결하였다. 서브클로닝이 제대로 되었는지를 코스모진텍의 universal 프라이머 중의 하나인 CMV30(5'-AATGTCGTAATAACCCCGCCCCGTTGACGC-3': 서열번호 8)로 서열 분석하여 100% 일치함을 확인하였다 (도 7). Here, the subcloning of the E4orf6 (GenBank AC_000008; also called E4 34K) gene was carried out by transferring the E4orf6 gene from the adenovirus backbone d1324-BstBI to the pFlag-CMV2 vector. For this, in dl324-BstBI using primers for E4orf6 PCR (forward 5'-GTACAAGCTTATGACTAC GTCCGGCGTTCC-3' containing HindIII: reverse 5'-CACCTCTAGACTACA TGGGGGTAGAGTCAT-3' containing SEQ ID NO: 6 and XbaI: SEQ ID NO: 7) PCR (initial denaturing: 95 2 min, denaturing: 95 30 sec, annealing: 58 30 sec, extension: 72 1 min 30 sec; 30 cycle) to amplify the E4orf6 coding gene region and then to HindIII/XbaI After double digestion, it was linked with pFlag-CMV2 digested with HindIII and XbaI. Whether the subcloning was done properly was confirmed by sequence analysis with CMV30 (5'-AATGTCGTAATAACCCCGCCCCGTTGAGCC-3': SEQ ID NO: 8), one of Cosmo Jintech's universal primers, to confirm 100% agreement (FIG. 7).

이상의 실험결과들로부터 E1B55K의 과대 발현 유도는 아데노바이러스 wild type 에서의 E1B55K의 주된 작용(E4orf6과 복합체를 이루어 p53 단백질의 분해 유도)과는 상반된 p53 프로모터에 직접적으로 혹은 간접적으로 작용하여 전사유도를 통해 p53 축적을 유도하는 새로운 작용을 발견하였다. 그리고 E1B55K의 발현 증가에 따른 MSC 세포사멸 증가 및 생존 신호 감소가 MSC에서 바이러스 생산능에 어떻게 영향을 주는지를 확인하기 위하여, 아데노바이러스 전달체를 이용하여 E1B55K를 외부에서 공급하여 MSC에서 바이러스 생산능 증가 여부를 다시 확인하여 보기로 했다. 이를 위해 다음과 같이 E1B55K 발현하는 복제불능 아데노바이러스를 제작하였다.From the above experimental results, the induction of overexpression of E1B55K directly or indirectly acts on the p53 promoter, which is opposite to the main action of E1B55K in the adenovirus wild type (inducing degradation of p53 protein by forming a complex with E4orf6) through transcriptional induction. A novel action inducing p53 accumulation was discovered. And in order to confirm how the increase in MSC apoptosis and the decrease in survival signal according to the increase in the expression of E1B55K affect the virus production capacity in MSC, E1B55K was supplied from the outside using an adenovirus carrier to determine whether the virus production capacity was increased in MSCs. I decided to check it out again. To this end, a replication-defective adenovirus expressing E1B55K was prepared as follows.

1) E1B55K 발현하는 복제불능 아데노바이러스(pCA14-E1B55K) 제작1) Preparation of replication-deficient adenovirus expressing E1B55K (pCA14-E1B55K)

아데노바이러스 셔틀벡터인 pCA14에 E1B55K 유전자를 클로닝하였다. E1B55K는 pBSK-3484 안에 포함되어 있으며 XbaI과 HindIII를 양 말단에 포함하는 형태로 프라이머 (sense 5'-TTCATCTAGAATGGAGCGAAGAAACCCATC-3'(XbaI): 서열번호 9, antisense 5'- GACGAAGCTTTCAATCTGTATCTTCATCGC -3 (HindIII): 서열번호 10)를 제작하여 PCR (initial denaturing: 95℃ 2분 후, denaturing: 95℃ 30초, annealing: 58℃ 30초, extension: 72℃ 2분; 30 cycle)로 증폭하고 XbaI/HindIII로 미리 절단된 pCA14 (Microbix, Canada) 안으로 연결하였다. 그 결과 pCA14 안으로 모든 E1B55K PCR 단편이 삽입된 것을 확인하였다 (도 8). 확인된 아데노바이러스 셔틀 벡터인 pCA14-E1B55K는 서열 확인 (도 9) 후 다시 XmnI 절단으로 선형화하며 아데노바이러스 벡터인 dl324-BstBI는 Bsp119I 절단으로 선형화하여 이 둘을 E. coli BJ5183에 동시형질전환(cotransformation)하여 상동재조합을 유도하여 E1B55K를 발현하는 아데노바이러스 벡터를 제작한 후 293A에 트랜스펙션 후 바이러스 생성을 유도하고 확대 생산하고 분리 정제한 후 역가를 산출하였다. The E1B55K gene was cloned into an adenovirus shuttle vector, pCA14. E1B55K is contained in pBSK-3484, and primers (sense 5'-TTCATCTAGAATGGAGCGAAGAAACCCATC-3'(XbaI): SEQ ID NO: 9, antisense 5'-GACGAAGCTTTCAATCTGTATCTTCATCGC-3 (HindIII): Sequence No. 10) was prepared and amplified by PCR (initial denaturing: 95°C after 2 minutes, denaturing: 95°C for 30 seconds, annealing: 58°C for 30 seconds, extension: 72°C for 2 minutes; 30 cycle) and pre-cleaved with XbaI/HindIII pCA14 (Microbix, Canada). As a result, it was confirmed that all E1B55K PCR fragments were inserted into pCA14 ( FIG. 8 ). The confirmed adenovirus shuttle vector, pCA14-E1B55K, was linearized by XmnI digestion again after sequence confirmation (FIG. 9), and the adenoviral vector dl324-BstBI was linearized by Bsp119I digestion, and the two were cotransformed into E. coli BJ5183. ) to induce homologous recombination to prepare an adenovirus vector expressing E1B55K, and then transfect 293A to induce virus production, expand production, separate and purify, and calculate titers.

pCA14 서열분석 전용 프라이머 (자체 제작 forward (hCMV): 5'-GGG AGGTCTATATAAGCAGAGCTCG-3': 서열번호 11, reverse (pCA14 SV40): 5'-CATGATCGATGCTAG ACGATCCAGA-3': 서열번호 12)로 정방향과 역방향으로 읽은 pCA14-E1B55K 플라스미드 클론 1, 2, 3, 4 중 1, 2, 3 일치함을 확인하였고 여기서 도 9는 샘플 3번 클론 플라스미드 DNA의 서열 분석 결과이다. 도 9에서 보이는 중간에 일치되지 않는 정방향의 두 군데 (red) 서열은 기존의 wild adenovirus type 5의 E1B55K의 첫 번째 염기인 a가 진뱅크의 AC_000008의 2019번이고 2048번 forward 프라이머 g가 a로 일부러 치환하여 KpnI 부위(GGTACC→AGTACC)를 제거하였고 2084번 forward (reverse의 red와 overlap) a가 t로 치환하여 HindIII 부위 (AAGCTT→TAGCTT) 를 일부러 제거하였다 (100% 상동). pCA14 sequencing-only primer (self-made forward (hCMV): 5'-GGG AGGTCTATATAAGCAGAGCTCG-3': SEQ ID NO: 11, reverse (pCA14 SV40): 5'-CATGATCGATGCTAG ACGATCCAGA-3': SEQ ID NO: 12) in forward and reverse directions It was confirmed that 1, 2, and 3 of the read pCA14-E1B55K plasmid clones 1, 2, 3, and 4 were identical. The two sequences (red) in the middle that do not match in the middle shown in FIG. 9 are the first base a of E1B55K of the existing wild adenovirus type 5, the 2019 number of AC_000008 of GenBank, and the 2048 forward primer g is deliberately a The KpnI site ( G GTACC→ A GTACC) was removed by substitution, and the 2084 forward (red and overlap of reverse) a was replaced with t, and the HindIII site ( A AGCTT→ T AGCTT) was intentionally removed (100% homology).

2) E1B55K 발현하는 바이러스가 감염된 MSC의 lysate에서 E1B55K 발현 확인2) Confirmation of E1B55K expression in lysate of MSC infected with E1B55K-expressing virus

E1B55K 발현을 위해 E1B55K에 대한 특이 항체를 제작 의뢰하여 확보한 polyclonal antibody에 의한 E1B55K 검출에 이상이 없음을 확인(도 10a)한 후 생산 및 정제한 바이러스의 MOI별 검출 결과 정상적인 발현이 이루어지고 있음을 웨스턴 블랏팅으로 확인하였다 (도 10b). 도 10a의 우측 도면은 좌측 도면의 raw data로서 Polyclonal 항체인 E1B55K의 정확한 크기와 밴드를 확인하고자 첨부하였다. 도 10a의 3번째 레인은 E1B55K를 발현하는 아데노바이러스 벡터 (dl324-E1B55K) DNA 3 μg을 PacI 절단 후 293A에 트랜스펙션하고 바이러스 생성 확인 후 수확한 soup을 인간 지방세포 유래 MSC-TERT에 감염시킨 것이며, 4번째 레인은 3번째 레인과 마찬가지로 진행시켜 얻은 soup과 플러스 세포를 냉동(freezing) 및 해동(thawing)하여 최종적인 soup을 감염시킨 것이고 5번째 레인은 처음 트랜스펙션 시 DNA 양을 2.5 μg으로 개시한 것이다. 도 10b는 5번째 레인의 조건으로 얻은 viral soup을 증폭하여 정제 후 바이러스의 감염능 입자를 계산하여 각 MOI별로 복제불능의 E1B55K를 발현하는 바이러스를 MSC-TERT에 감염시켰을 때 MOI가 증가함에 따라 E1B55K에 해당하는 band의 강도도 증가하고 있음을 확인함으로써 E1B55K에 대한 다클론 항체가 정상적으로 잘 작동되고 있음을 확인하였다. After confirming that there is no abnormality in E1B55K detection by the polyclonal antibody obtained by requesting production of a specific antibody for E1B55K expression for E1B55K expression (Fig. It was confirmed by Western blotting (Fig. 10b). The right figure of Figure 10a is the raw data of the left figure, and was attached to confirm the exact size and band of the polyclonal antibody E1B55K. In the third lane of Figure 10a, 3 μg of E1B55K-expressing adenovirus vector (dl324-E1B55K) DNA was transfected into 293A after PacI digestion, and the soup harvested after confirming virus production was infected with human adipocyte-derived MSC-TERT. The 4th lane is the final soup by freezing and thawing the soup and plus cells obtained in the same way as the 3rd lane, and the 5th lane is 2.5 μg of DNA at the time of first transfection. it started with Figure 10b shows the infectivity particles of the virus after amplifying and purifying the viral soup obtained under the conditions of the 5th lane, and infecting the virus expressing the replication-incompetent E1B55K by each MOI with MSC-TERT. As the MOI increases, E1B55K It was confirmed that the polyclonal antibody against E1B55K was operating normally by confirming that the intensity of the band corresponding to was also increased.

E1B55K에 대한 특이 항체인 다클론 항체의 제작 과정은 다음과 같다. The production process of the polyclonal antibody, which is a specific antibody against E1B55K, is as follows.

먼저, E1B55K의 N 말단 부위에 위치한 펩티드 서열 (MERRNPSERGVPAGFSGHASVESGC: 서열번호 13)을 합성하고 BSA (bovine serum albumin)을 면역원 carrier로 컨쥬게이션시킨 후 New Zealand White rabbits에 예방 접종(immunization)시켜 혈청을 정제하여 얻었다 (GW Vitek, Korea).First, a peptide sequence located at the N-terminal site of E1B55K (MERRNPSERGVPAGFSGHASVESGC: SEQ ID NO: 13) was synthesized, and BSA (bovine serum albumin) was conjugated to an immunogen carrier, and then New Zealand White rabbits were immunized to purify the serum. obtained (GW Vitek, Korea).

3) 인간 지방 MSC-TERT 에서 E1B55K 발현 정도에 따른 바이러스 생산 비교 → 유전자 이입에 따른 MSC의 바이러스 생산능 획기적 확대 검증3) Comparison of virus production according to E1B55K expression level in human fat MSC-TERT → Verification of dramatic expansion of virus production capacity of MSC according to transgenic

먼저, E1B55K 발현하는 플라스미드 (pcDNA3.1-E1B55K) 1μg을 인간 지방세포 유래 MSC-TERT에 트랜스펙션 (도 11) 또는 E1B55K 발현하는 복제 불능 defective 아데노바이러스를 MOI별로 감염 (도 12) 4시간 후 배지 교체하고 종양 살상 아데노바이러스 (YSC-02)를 100 MOI로 감염 후 48시간이 지닌 다음에 배지와 세포들을 모두 수거한 후 냉동(freezing)과 해동(thawing) 하여 바이러스를 최대한 여기시킨 다음 원심분리하여 얻은 상등액 안에 감염능있는 바이러스의 적정(titration)을 진행한 결과를 보여주고 있다. 그 결과, E1B55K가 발현하는 MSC-TERT에서 종양 살상 아데노바이러스 감염 후 대조군과 비교 시 바이러스 생산이 확연히 증가함을 확인하였다 (도 12). First, 1 μg of E1B55K-expressing plasmid (pcDNA3.1-E1B55K) was transfected into human adipocyte-derived MSC-TERT (Fig. 11) or E1B55K-expressing replication-defective adenovirus was infected by MOI (Fig. 12) after 4 hours. After changing the medium, and 48 hours after infection with oncolytic adenovirus (YSC-02) at 100 MOI, all medium and cells were collected, and then frozen and thawed to maximize virus excitation, followed by centrifugation. It shows the results of titration of the infective virus in the supernatant obtained by doing so. As a result, it was confirmed that the virus production was significantly increased in MSC-TERT expressing E1B55K compared to the control group after oncolytic adenovirus infection ( FIG. 12 ).

실시예Example 2:2: 획기적 바이러스 생산 증가 유도 및 탑재유전자 발현시점 조절, 및 원천적 종양원성 제어 기술의 동시 실현은 E1B55K의 시간차 발현 조절 시스템 도입으로 가능해짐 The simultaneous realization of innovative virus production increase induction, payload gene expression time control, and original tumorigenicity control technology is made possible by the introduction of the E1B55K time difference expression control system.

MSC 세포주 대량 생산을 위해 불가피하게 도입된 TERT 유전자에 의한 제어 종양원성 가능성 증가는 E1B55K가 바이러스 복제 증가 유도뿐만 아니라 MSC 세포의 전반적인 생존능 감소를 유도하는 것을 처음으로 규명함으로써 해결 방안을 마련할 수 있었다. 즉, E1B55K 유전자의 발현시점을 시간차 유도하여 MSC의 계대 증식을 가능하게 하여 cell banking을 통한 대량 생산 가능하게 함과 동시에 MSC의 종양원성(tumorigenesis)을 원천적으로 차단시키는 제어기술 개발하였다. 이로서 바이러스/MSC 치료제의 혁신적 전기를 마련했다는데 큰 의의가 있다. The increase in the control tumorigenic potential by the TERT gene, which was inevitably introduced for mass production of MSC cell lines, could be solved by first finding that E1B55K not only induces an increase in viral replication but also induces a decrease in the overall viability of MSC cells. In other words, a control technology was developed to fundamentally block the tumorigenesis of MSCs while at the same time enabling mass production through cell banking by inducing the time difference in the expression time of the E1B55K gene to enable passage growth of MSCs. This has great significance in that it has prepared an innovative turning point for virus/MSC therapeutics.

Retro-X™Tet-One™ 유도 발현 시스템 (다카라 cat# 634307)은 도 13의 프로토콜을 참조하였다. The Retro-X™ Tet-One™ inducing expression system (Takara cat# 634307) was referenced in the protocol of FIG. 13 .

1) pRetro-X-Tet-one-puro-E1B55K 제작1) Produced pRetro-X-Tet-one-puro-E1B55K

Retro-X-Tet-one-puro vector 플라스미드에 E1B55K 유전자를 넣기 위해서는 양 말단에 각각 EcoRI과 BamHI 인식부위를 가져야 한다. 인식부위 가지는 E1B55K 제작 위해 pCA14-E1B55K를 주형으로 사용하였으며 E1B55K In-fusion EcoRI sense primer는 5'-CCCTCGTAAAGAATTCATGGAGCGAAGAAACCCATCTGAG-3' (서열번호 14)이며 E1B55K In-fusion BamHI antisense primer는 5'-GAGGTGGTCTGGATCCTCAATCTGTATCTTCATCGCTAGA-3' (서열번호 15)이다. In order to insert the E1B55K gene into the Retro-X-Tet-one-puro vector plasmid, it must have EcoRI and BamHI recognition sites at both ends, respectively. To construct E1B55K with recognition site, pCA14-E1B55K was used as a template. E1B55K In-fusion EcoRI sense primer was 5'-CCCTCGTAAAGAATTCATGGAGCGAAGAAACCCATCTGAG-3' (SEQ ID NO: 14), and E1B55K In-fusion BamHI antisense primer was 5'-TAGAGG-3'TGGTCTGGATCC (SEQ ID NO: 15).

PCR 조건은 아래와 같다(도 14). PCR conditions are as follows (FIG. 14).

Initial denaturing을 95℃ 2분으로 한 후 denaturing 95℃ 40초, annealing: 61℃ 40초, extension: 72℃ 1분 50초; 30 cycle을 진행하였다. Initial denaturing at 95°C for 2 minutes, denaturing at 95°C for 40 seconds, annealing: 61°C for 40 seconds, extension: 72°C for 1 minute and 50 seconds; 30 cycles were performed.

PCR 진행은 Promega(#M750B) 제품 사용하였다.PCR was carried out using Promega (#M750B) products.

In-fusion 방식의 외부 유전자 도입 방식으로 E1B55K가 pRetro-X-Tet one에 제대로 삽입된 construct 플라스미드 (도 15의 sample pRetro-X-Tetone-E1B55K #13) 를 확보한 후 서열 분석하여 최종적으로 도입을 확인하였다 (도 17). 그 다음 독시사이클린에 의해 실제로 삽입된 유전자인 E1B55K 단백질이 발현 유도되는지 확인하였다 (도 18). 도 18의 5번째 레인에서와 같이 독시사이클린 (2.5 μg/ml) 존재 하에서만 pRetro-X-Tetone-E1B55K 플라스미드가 A549에 트랜스펙션되었을 때 E1B55K가 발현 유도되었으며, 독시사이클린이 존재하지 않은 경우의 동일한 플라스미드가 트랜스펙션되었을 경우에는 발현 유도가 되지 않음을 확인하였다. 즉, 전혀 leakage 현상이 일어나지 않았다. 맨 오른쪽 레인은 E1B55K가 constitutive 하게 발현하게 하여 E1B55K 발현을 확인한 positive condition이다. By the in-fusion method of external gene introduction, a construct plasmid in which E1B55K was properly inserted into pRetro-X-Tet one (sample pRetro-X-Tetone-E1B55K #13 in FIG. 15) was secured and sequenced to finally be introduced. was confirmed (FIG. 17). Then, it was confirmed whether the expression of the E1B55K protein actually inserted by doxycycline was induced ( FIG. 18 ). As in the 5th lane of FIG. 18, when pRetro-X-Tetone-E1B55K plasmid was transfected into A549 only in the presence of doxycycline (2.5 μg/ml), expression of E1B55K was induced, and the same plasmid in the absence of doxycycline When transfected, it was confirmed that expression was not induced. That is, no leakage occurred at all. The rightmost lane is a positive condition confirming the expression of E1B55K by constitutive expression of E1B55K.

제작에 사용된 pRetro-X-tetone-puro-E1B55K 벡터는 도 16에 나타내었다.The pRetro-X-tetone-puro-E1B55K vector used for construction is shown in FIG. 16 .

2) pRetro-X-tetone-puro-E1B55K 발현 확인 2) Confirmation of pRetro-X-tetone-puro-E1B55K expression

pRetro-X-Tetone-puro-E1B55K 플라스미드 트랜스펙션 후 독시사이클린 처리 시 독시사이클린 양에 따른 pRetro-X-tetone-puro-E1B55K에서 E1B55K의 발현을 확인하였다. tet one system으로 E1B55K의 시간차 발현 조절 제어가 가능한지를 알아보기 위하여 tet one system을 도입한 경우 독시사이클린 처리 전에는 E1B55K의 발현이 전혀 일어나지 않고 있음을 확인하였다(도 19). 즉, leakage 일어나지 않음을 확인하였다. 반면에 독시사이클린 0.05 μg/ml 라는 매우 적은 농도가 처리되더라도 즉시 E1B55K 발현이 유도되었다. 이것은 독시사이클린 처리 전에는 cell survival 유지가 가능하며, 종양 도달 후 독시사이클린 처리 후 즉시 발현 유도하게 할 수 있음을 의미한다. After transfection with pRetro-X-Tetone-puro-E1B55K plasmid, expression of E1B55K was confirmed in pRetro-X-tetone-puro-E1B55K according to the amount of doxycycline during doxycycline treatment. In order to examine whether the tet one system can control the time difference expression of E1B55K, it was confirmed that the expression of E1B55K did not occur at all before doxycycline treatment when the tet one system was introduced (FIG. 19). That is, it was confirmed that leakage did not occur. On the other hand, even when a very small concentration of doxycycline 0.05 μg/ml was treated, E1B55K expression was induced immediately. This means that cell survival can be maintained before doxycycline treatment, and expression can be induced immediately after doxycycline treatment after reaching a tumor.

시간 차 바이러스 방출 검증은 다음과 같이 2차 검증하였다. Time difference virus release verification was secondarily verified as follows.

인간 지방 MSC-TERT에 pRetro-tetone-E1B55K 플라스미드 트랜스펙션 후 (4시간) RFP (red florescence protein) 발현하는 종양 살상 아데노바이러스 감염 후 (4시간) 독시사이클린 처리 유무에 따른 바이러스 생산을 48시간 후 비교하였다. After transfection of human fat MSC-TERT with pRetro-tetone-E1B55K plasmid (4 hours), after infection with oncolytic adenovirus expressing RFP (red florescence protein) (4 hours), virus production with and without doxycycline treatment was compared after 48 hours did

그 결과, 독시사이클린 처리 시 바이러스 생산이 10배 이상 뚜렷하게 증가하는 것을 확인하였다 (도 20). As a result, it was confirmed that the virus production was significantly increased more than 10-fold during doxycycline treatment (FIG. 20).

3) MSC-TERT-tetoneE1B55K 세포주 확립3) Establishment of MSC-TERT-tetoneE1B55K cell line

아데노바이러스의 early region 1B-55kDa인 E1B55K를 인코딩하는 유전자를 Retro-X-Tet-One inducible expression system (TAKARA Bio Inc.)에 도입한 후 MSC-TERT에 감염시켜 독시사이클린 존재 시 E1B55K 발현하는 클론들을 확보하였다. 이를 위해 GP2-293 패키징 세포에 pRetroX-TetOne-E1B55K과 막 단백질을 인코딩하는 pAmpho 벡터 (다카라 키트 안에 포함됨)를 같이 트랜스펙션하였다. 48시간 후 여과시킨 retroviral supernatant를 타겟 세포인 MSC-TERT에 감염시켰다. 배양과정 중 puromycin으로 선별한 모든 클론들을 독시사이클린 (2.5 μg/ml) 존재한 조건에서 E1B55K의 발현 유도 (도 21)와 p53의 축적 (도 22)이 동시에 진행됨을 재차 웨스턴 블랏팅으로 확인하였다. The gene encoding E1B55K, which is early region 1B-55kDa of adenovirus, was introduced into Retro-X-Tet-One inducible expression system (TAKARA Bio Inc.) and then infected with MSC-TERT. Clones expressing E1B55K in the presence of doxycycline were obtained. To this end, GP2-293 packaging cells were transfected with pRetroX-TetOne-E1B55K and the pAmpho vector encoding the membrane protein (included in the Takara kit). After 48 hours, the filtered retroviral supernatant was infected with the target cell, MSC-TERT. It was confirmed again by Western blotting that induction of E1B55K expression (FIG. 21) and accumulation of p53 (FIG. 22) proceed simultaneously in all clones selected with puromycin during the culture process in the presence of doxycycline (2.5 μg/ml).

이상의 결과로부터 탑재 유전자인 E1B55K의 발현시점을 독시사이클린 처리에 따라 조절함으로써 바이러스 생산 유도를 원하는 시점에 증가시킬 수 있게 됨을 의미하였다. (E1B55K 의 유전자 발현 유도가 진행되어야 하므로 독시사이클린 처리 후 최소 24시간 정도 경과후에 바이러스의 증가가 개시될 것으로 보인다.)From the above results, it was meant that the induction of virus production could be increased at a desired time point by regulating the expression point of the load gene, E1B55K, according to doxycycline treatment. (Since E1B55K gene expression induction must proceed, it is likely that the virus will start to increase after at least 24 hours after doxycycline treatment.)

4) 원천적 종양원성 제어 기술 실현4) Realization of original tumorigenicity control technology

도 21의 클론 2번 또는 10번의 종양원성 제어가 가능한지를 확인하였다. 이를 위해 클론세포주가 분주된 6-well에 독시사이클린 처리 후 장기간(~14일) 배양을 실시하였다. It was confirmed whether the tumorigenicity control of clones 2 or 10 of FIG. 21 was possible. For this purpose, 6-wells in which cloned cell lines were dispensed were treated with doxycycline and then cultured for a long period of time (~14 days).

그 결과, 독시사이클린 처리 (1.25 μg/ml) 배양 2주가 경과하면 거의 대부분의 세포들의 생존능이 사라지는 것을 확인하였다(도 23). 이로써 종양 살상 바이러스 감염에 의한 용해(lysis) 이외 감염되지 않은 MSC라 할지라도 E1B55K 발현 레트로바이러스에 의해 감염되어 선별된 사용 세포주들은 결국에는 세포사멸에 이르게 되므로 종양원성의 가능성은 원천적으로 배제된다. As a result, it was confirmed that the viability of most cells disappeared after 2 weeks of doxycycline treatment (1.25 μg/ml) culture ( FIG. 23 ). As a result, even uninfected MSCs other than lysis by oncolytic virus infection, the selected cell lines infected with the E1B55K-expressing retrovirus eventually lead to apoptosis, so the possibility of tumorigenicity is fundamentally excluded.

실시예 3:Example 3: 종양 타겟팅 획기적 증가 확립 - Tumor homing 향상 요인 발굴 Establishment of a breakthrough in tumor targeting - Discovering factors to improve tumor homing

인간 지방 MSC-TERT에 GRP78 추가 발현 유도함으로 종양 향성(tumor tropism) 관련 마커 발현을 확인하였다. The expression of tumor tropism-related markers was confirmed by inducing additional expression of GRP78 in human adipose MSC-TERT.

GRP78의 증가에 의해 MSC homing의 각 단계에 작용하는 인자들의 발현이 모두 증가하고 있음을 확인하였다 (도 24a).It was confirmed that the expression of all factors acting on each step of MSC homing was increased by the increase of GRP78 (FIG. 24a).

GRP78 발현이 확실히 되고 있음을 확인하기 위해 인간 MSC-TERT에 pcDNA3.1-GRP78 (2 ㎍) 트랜스펙션하여 GRP78의 mRNA 발현 증가를 확인하였다 (도 24b). In order to confirm that GRP78 expression is confirmed, human MSC-TERT was transfected with pcDNA3.1-GRP78 (2 μg) to confirm the increase in the mRNA expression of GRP78 ( FIG. 24b ).

1) pcDNA3.1 hygro (+)로의 GRP78 클로닝1) GRP78 cloning into pcDNA3.1 hygro (+)

GRP78 발현량이 높은 간암 세포주인 SNU449에서 Trizol로 RNA 추출하였다. 추출한 RNA는 invirogen의 SuperScript™ First-Strand Synthesis System for RT-PCR kit를 이용하여 역전사하였다. 그리고 PCR 진행하기 위하여 사용한 프라이머는 정방향으로는 XhoI 부위를 추가하고 역방향으로는 XbaI 부위를 추가하여 서열 제작하였다. Forward (5'-GATTCTCGAGATGAAGCTCTCCCTGG-3': 서열번호 16), Reverse (5'-GGCCTCTAGACTACAACTCATCTTTT-3': 서열번호 17) 프라이머를 사용하여 PCR (initial denaturing 95℃ 2분 후 denaturing: 95℃ 40초, annealing: 58℃ 40초, extension: 72℃ 2분 30초; 30 cycle) 클로닝하였다. PCR하여 XhoI/XbaI로 절단 후, 백본인 pcDNA3.1-hygro 벡터 또한 XhoI/XbaI로 절단하여 연결하였다. 박테리아에 형질전환 후 얻은 콜로니들을 배양하였다. 이렇게 얻은 각각의 플라스미드들을 XhoI/XbaI로 동시 절단하여 삽입을 확인하여 5번 플라스미드에서만 크기가 일치하는 삽입을 확인하였다 (도 25). 확인된 5번의 pcDNA3.1-GRP78을 간암 세포주인 SNU449에 트랜스펙션 후 웨스턴 블랏팅으로GRP78의 단백질 발현 증가를 확인하였다 (도 26). 그리고 5번 샘플 플라스미드를 서열 분석한 결과 NCBI NM_005347과 100% 상동성을 보였다 (도 27). RNA was extracted with Trizol from SNU449, a liver cancer cell line with high GRP78 expression. The extracted RNA was reverse transcribed using invirogen's SuperScript™ First-Strand Synthesis System for RT-PCR kit. And the primers used for PCR were sequenced by adding an XhoI site in the forward direction and an XbaI site in the reverse direction. Forward (5'-GATTCTCGAGATGAAGCTCTCCCTGG-3': SEQ ID NO: 16), Reverse (5'-GGCCTCTAGACTACAACTCATCTTTT-3': SEQ ID NO: 17) using primers PCR (initial denaturing 95 ° C. 2 minutes after denaturing: 95 ° C. 40 seconds, annealing : 58 40 sec, extension: 72 2 min 30 sec; 30 cycle) cloned. After PCR and digestion with XhoI/XbaI, the backbone pcDNA3.1-hygro vector was also digested with XhoI/XbaI and ligated. Colonies obtained after transformation into bacteria were cultured. Each of the plasmids thus obtained was simultaneously digested with XhoI/XbaI to confirm the insertion, and the insertion of the same size was confirmed only in plasmid 5 ( FIG. 25 ). After transfection of the identified 5 pcDNA3.1-GRP78 into the liver cancer cell line SNU449, the increase in GRP78 protein expression was confirmed by Western blotting (FIG. 26). And as a result of sequence analysis of sample plasmid No. 5, it showed 100% homology with NCBI NM_005347 (FIG. 27).

2) pLNCX neo로의 GRP78 클로닝 2) Cloning of GRP78 into pLNCX neo

GRP78 유전자를 MSC-TERT 또는 MSC-TERT-tetonE1B55K 에 도입하기 위하여 다음과 같이 수행하였다. In order to introduce the GRP78 gene into MSC-TERT or MSC-TERT-tetonE1B55K, it was performed as follows.

레트로바이러스 벡터인 pLNCXneo에 GRP78을 도입하기 위하여 pcDNA3.1-GRP78 vector에서 XhoI/PmeI으로 절단하여 GRP78 부위를 빼내어 이를 미리 XhoI/PmeI으로 절단한 pLNCXneo에 연결하여 삽입하였다.In order to introduce GRP78 into the retroviral vector pLNCXneo, it was cut with XhoI/PmeI from pcDNA3.1-GRP78 vector to extract the GRP78 site, which was then ligated to pLNCXneo previously cut with XhoI/PmeI and inserted.

pLNCX neo는 기존의 LNCX 안의 cloning site인 HindIII-HpaI-ClaI에서 HindIII-PmlI-BstXI-NotI-XhoI-SalI-ApaI-PmeI-HpaI-ClaI으로 제한효소 인식부위 증가시켜 자체 제작하였다 (도 28). pLNCX neo was produced by increasing the restriction enzyme recognition site from HindIII-HpaI-ClaI, which is a cloning site in the existing LNCX, to HindIII-PmlI-BstXI-NotI-XhoI-SalI-ApaI-PmeI-HpaI-ClaI (FIG. 28).

이때 strand sequence는 다음과 같다. In this case, the strand sequence is as follows.

Top 5'-AGCTTCACGTGCCAGCACAGTGGCGGCCGCTCGAGTCGACGGGCCCGTTTAAACGTTAACAT-3', (서열번호 18)Top 5'-AGCTTCACGTGCCAGCACAGTGGCGGCCGCTCGAGTCGACGGGCCCGTTTAAACGTTAACAT-3', (SEQ ID NO: 18)

Bottom 5'-CGATGTTAACGTTTAAACGGGCCCGTCGACTCGAGCGGCCGCCACTGTGCTGGCACGTGA-3 (서열번호 19). Bottom 5'-CGATGTTAACGTTTAAACGGGCCCGTCGACTCGAGCGGCCGCCACTGTGCTGGCACGTGA-3 (SEQ ID NO: 19).

LNCXneo-GRP78 삽입 여부 확인은 대조구로 pLNCXneo (control)와 pcDNA3.1-GRP78 (GRP78 유전자 제공 플라스미드)를 각각 HindIII/PmeI으로 절단하여 선형화된 pLNCXneo와 pcDNA3.1-GRP78로부터 유래된 GRP78 단편을 연결하여 DH5αcompetent cell에 형질전환 후 플라스미드를 획득하여 pLNCXneo-GRP78 후보 construct들 (샘플 1~24)을 동시 절단하여 2,5,9,11,12,20,21번 샘플에 삽입된 것을 확인하였다 (도 29).To check whether LNCXneo-GRP78 is inserted, pLNCXneo (control) and pcDNA3.1-GRP78 (GRP78 gene providing plasmid) as a control are cut with HindIII/PmeI, respectively, and linearized by linking pLNCXneo and GRP78 fragment derived from pcDNA3.1-GRP78. After transformation into DH5α competent cells, a plasmid was obtained and pLNCXneo-GRP78 candidate constructs (samples 1-24) were simultaneously cut and inserted into samples 2,5,9,11,12,20,21 (FIG. 29) ).

3) MSC-TERT-GRP78 세포주 제작3) MSC-TERT-GRP78 cell line production

플래티눔-A 패키징 세포(Cell Biolabs)에 레트로바이러스 벡터인 pLNCXneo-GRP78을 트랜스펙션하여 48시간이 경과한 후 배지를 여과시켰다. 여과시켜 얻은 레트로바이러스를 포함된 배지 용액을 MSC-TERT에 감염시켜 G418 (500㎍~600μg/㎖)에 저항성을 가지는 세포 클론들을 얻은 후 스크리닝하여 GRP78 및 MMP2 발현이 뚜렷한 클론 2번과 4번을 선별하였다 (도 30). Platinum-A packaging cells (Cell Biolabs) were transfected with pLNCXneo-GRP78, a retroviral vector, and after 48 hours, the medium was filtered. The medium solution containing retrovirus obtained by filtration was infected with MSC-TERT to obtain cell clones resistant to G418 (500 μg~600 μg/ml), and then screened to obtain clones 2 and 4 with clear GRP78 and MMP2 expression. was selected (FIG. 30).

4) 유전자 이입한 MSC의 종양 타겟팅: 매우 빠른 시간 내에 종양부위로만 특이적으로 도달 조건 확인 4) Tumor targeting of transgenic MSCs: Confirmation of conditions for reaching specific tumor sites within a very short time

① MSC-TERT-GRP78의 종양타겟팅 검증 ① Tumor targeting verification of MSC-TERT-GRP78

6주령의 BALB/c 흉선 누드 마우스의 어깨 부위에 2 × 106 개의 SNU398 세포 (간암 세포주)을 피하에 이식하고 7일 경과 후 꼬리 정맥으로 반딧불이 루시퍼라제를 발현하는 복제불능의 아데노바이러스를 감염시킨 1 × 106 개의 MSC-TERT-GRP78 주사하였다. 발광을 인식하는 IVIS (in vivo imaging system) 장치를 사용하기 위하여 마우스의 복강으로 마우스 kg 당 150 mg D-luciferin을 주사하였다. In vivo에서 루시퍼라제 발현하는 아데노바이러스 감염된 MSC-TERT-GRP78의 체내 분포를 꼬리정맥주사한지 6시간후 IVIS Spectrum System (PerkinElmer) 을 사용하여 영상 촬영하여 관찰하였다. 이 실험의 특징은 GRP78 유전자 이입한 MSC-TERT-GRP78가 종양 이동능이 얼마나 있는지를 정확하게 구별하기 위하여 간, 폐와 같은 내부장기와 구별하기 위해 어깨 쪽에 종양 형성하게 함으로써 MSC-TERT-GRP78의 도달 부위가 매우 빠른 시간 내에 다른 장기로의 흡착 없이 종양조직 부위로 모여든 것을 명확하게 확인하였다 (도 31).2 × 10 6 SNU398 cells (liver cancer cell line) were subcutaneously transplanted into the shoulder of 6-week-old BALB/c thymic nude mice, and 7 days later, the tail vein was infected with replication-competent adenovirus expressing firefly luciferase. 1 × 10 6 MSC-TERT-GRP78 were injected. In order to use an in vivo imaging system (IVIS) device that recognizes luminescence, 150 mg of D-luciferin per kg of mouse was injected into the abdominal cavity of the mouse. In vivo distribution of MSC-TERT-GRP78 infected with adenovirus expressing luciferase was observed by imaging using an IVIS Spectrum System (PerkinElmer) 6 hours after tail vein injection. The characteristic of this experiment is that the GRP78 transgenic MSC-TERT-GRP78 reaches the target site of MSC-TERT-GRP78 by allowing it to form a tumor on the shoulder to distinguish it from internal organs such as liver and lungs in order to accurately distinguish how much tumor migrating ability is. It was clearly confirmed that the tumors gathered into the tumor tissue site within a very short time without adsorption to other organs (FIG. 31).

② 유전자 이입 완료된 최종 타입 MSC-TERT-tetoneE1B55K-GRP78의 종양 타겟팅 검증 ② Validation of tumor targeting of the final type MSC-TERT - tetoneE1B55K-GRP78 that has been introgressed

6주령의 BALB/c 흉선 누드 마우스의 어깨 부위에 8 × 106 개의 A549 세포 (폐암 세포주), 2 × 106 개의 SNU398 세포 (간암 세포주) 또는 2 × 106 개의 MiaPaCa-2 세포 (췌장암 세포주)를 피하에 이식하고 7일 경과 후 꼬리정맥으로 반딧불이 루시퍼라제를 발현하는 복제 불능 아데노바이러스를 감염시킨 1 × 106 개의 MSC-TERT-tetoneE1B55K-GRP78을 주사하였다. 발광을 인식하는 IVIS 장치를 사용하기 위하여 마우스의 복강으로 마우스 kg 당 150 mg D-luciferin을 주사하였다. In vivo에서 루시퍼라제를 발현하는 아데노바이러스 감염된 MSCs의 체내 분포를 IVIS Spectrum System (PerkinElmer)을 사용하여 6시간 또는 24시간 후 관찰하였다. 8 × 10 6 A549 in the shoulder region of 6-week-old BALB/c thymic nude mice Cells (lung cancer cell line), 2 × 10 6 SNU398 cells (liver cancer cell line) or 2 × 10 6 MiaPaCa-2 cells (pancreatic cancer cell line) were transplanted subcutaneously and cloned into tail vein expressing firefly luciferase 7 days later 1 × 10 6 MSC-TERT-tetoneE1B55K-GRP78 infected with the defective adenovirus were injected. In order to use the IVIS device that recognizes luminescence, 150 mg of D-luciferin per kg of mouse was injected intraperitoneally. In vivo distribution of adenovirus-infected MSCs expressing luciferase was observed after 6 or 24 hours using the IVIS Spectrum System (PerkinElmer).

그 결과, 앞의 타겟팅 실험 ①과 마찬가지로 간, 폐와 같은 내부장기와 구별하기 위해 어깨 쪽에 종양 형성하게 함으로써 MSC의 도달 부위가 매우 빠른 시간 내에 다른 장기로의 흡착 없이 종양 조직 부위로 모여든 것을 명확하게 확인하였다(도 32). 여기서 알 수 있듯이 GRP78 이 포함된 최종 타입의 MSC-TERT-tetoneE1B55K-GRP78에서 암종에 구별 없이 GRP78이 없는 MSC에 비하여 도 31과 같이 매우 빠른 시간 안에 종양 부위로 이동한 것을 볼 수 있으며, 그 차이는 루시퍼라제 활성 강도 수치로 비교할 때 확연하게 강도 차이가 있는 것을 확인할 수 있다 (종양에서의 발광 강도에 따라 최소 10배에서 최대 100 이상). 이는 종양 타겟팅이 매우 신속하고 정확하게 일어나고 있음을 알 수 있다. 여기서 E1B55K 는 독시사이클린을 먹이에 포함시키지 않았기 때문에 발현되지 않는다. As a result, as in the previous targeting experiment ①, by allowing tumors to form on the shoulder to distinguish them from internal organs such as liver and lungs, it was clear that the MSCs reached the site of the tumor within a very short time without adsorption to other organs. was confirmed (FIG. 32). As can be seen here, it can be seen that the final type MSC-TERT-tetoneE1B55K-GRP78 containing GRP78 migrated to the tumor site in a very short time as shown in FIG. 31, compared to MSC without GRP78, regardless of carcinoma. When compared with the luciferase activity intensity value, it can be seen that there is a significant difference in intensity (from a minimum of 10 times to a maximum of 100 or more depending on the luminescence intensity in the tumor). It can be seen that tumor targeting is taking place very quickly and accurately. Here, E1B55K is not expressed because doxycycline was not included in the diet.

이러한 종양으로의 루시퍼라제 발현하는 MSC-GRP78의 놀라우리만치 신속하고 정확한 trafficking 및 다양한 종양타입에 대한 타겟팅은 MSC-GRP78의 종양 진단에 활용할 수 있는 가능성을 매우 높인다. 마우스 1차 모델에서는 고형 암을 인위적으로 피하에 심어놓고 MSC-GRP78을 이동시키게 함으로써 종양 부위를 확인한 것이지만 체내 존재하는 전이형 모델에서도 같은 방식으로 종양 존재하면 종양 부위로 전달되어 발광하게 하거나 혹은 보다 resolution이 좋은 동위원소를 라벨링하여 종양을 검출 가능할 수 있게 된다. 이는 종양 진단에 응용 가능하며 장기적으로 종양 진단과 동시에 치료까지도 가능한 OV/MSC 복합체 제작이 가능해진다. The surprisingly rapid and accurate trafficking of luciferase-expressing MSC-GRP78 into these tumors and targeting to various tumor types greatly increases the possibility of using MSC-GRP78 for tumor diagnosis. In the mouse primary model, the tumor site was identified by artificially implanting a solid cancer subcutaneously and allowing MSC-GRP78 to migrate. By labeling this good isotope, the tumor can be detected. This can be applied to tumor diagnosis, and in the long term, it becomes possible to manufacture an OV/MSC complex that can diagnose and treat tumors at the same time.

③ 유전자 이입 완료된 최종 타입 MSC-TERT-tetoneE1B55K-GRP78의 종양 내 침투 (infiltration) 확인 ③ Confirmation of infiltration into the tumor of the final type MSC-TERT-tetoneE1B55K-GRP78 that has been transfected

최종 타입의 MSC-TERT-tetoneE1B55K-GRP78가 종양 부위로 도달된 것을 확인하였고 실제로 도달된 MSC가 종양 조직 내로 침투하는지 확인하기 위하여 다음과 같이 실험하였다.It was confirmed that the final type of MSC-TERT-tetoneE1B55K-GRP78 reached the tumor site.

먼저, A549 세포를 마우스의 피하조직에 이식하여 종양을 형성시켰다. 그런 다음 최종 타입의MSC 세포 (MSC-TERT-tetoneE1B55K-GRP78)를 fluorescent cell tracker probe (Invitrogen, C34565)로 라벨링시킨 후 마우스 꼬리 정맥으로 주사하였다. 주사 24시간, 48시간 및 72시간이 경과한 후 종양 조직을 적출하고 조직 section한 후 형광 현미경으로 형광 부위를 확인하였다. 도 33에서 보듯이, GRP78을 가지는MSC가 종양 내로 훨씬 많이 존재하는 것을 확인할 수 있었다. GRP78이 없는 MSC의 경우 낮은 형광강도로 종양 경계면에 주로 머물러 있음을 관찰하였다. First, A549 cells were transplanted into the subcutaneous tissue of a mouse to form a tumor. Then, the final type of MSC cells (MSC-TERT-tetoneE1B55K-GRP78) were labeled with a fluorescent cell tracker probe (Invitrogen, C34565) and injected into the tail vein of the mouse. After 24 hours, 48 hours, and 72 hours after injection, the tumor tissue was excised, and the fluorescence site was confirmed with a fluorescence microscope after tissue section. As shown in FIG. 33 , it was confirmed that MSCs having GRP78 were present much more in the tumor. In the case of MSC without GRP78, it was observed that it mainly stayed at the tumor interface due to low fluorescence intensity.

④ 종양 조직 내 아데노바이러스 관련 단백질의 발현 확인④ Confirmation of expression of adenovirus-related proteins in tumor tissue

종양 조직 안에 침투한 MSC-TERT-tetoneE1B55K-GRP78로부터 바이러스가 방출되어 종양세포들을 감염시키고 바이러스 생산 후 일정기간 바이러스가 복제 및 유지되는지를 확인하기 위하여 다음과 같이 실험하였다.The virus was released from MSC-TERT-tetoneE1B55K-GRP78 infiltrating the tumor tissue to infect tumor cells.

6주령의 BALB/c 흉선 누드 마우스의 옆구리 부위에 8 × 106 개의 A549 세포 (폐암 세포주))을 피하에 이식하고 종양 크기가 평균 150 mm3에 도달한 마우스들을 각각 2마리씩 꼬리 정맥으로 shHSP27-shTGFβ1을 발현하는 종양 살상 아데노바이러스로 감염된 1 × 106 개의 MSC-TERT-tetoneE1B55K-GRP78을 주사하였다. 그리고 3일 지난 후에 추가로 shHSP27-shTGFβ1을 발현하는 종양 살상 아데노바이러스가 감염된 1 × 106 개의 MSC-TERT-tetoneE1B55K-GRP78을 주사하였다. 그리고 두 번째 주사 후 7일째 각 그룹 마우스들의 종양을 적출하여 종양 section한 샘플들을adenovirus type 5 특이 항체 (Abcam, Cambridge, UK) 로 반응시켜 2차 항체로 DAB 발색 반응시키고 헤마톡실린 핵 염색으로 면역조직화학을 위한 대조염색을 진행하였다. 이때 모든 그룹에 독시사이클린 (625 mg/kg)이 포함된 먹이를 사료로 공급하였다. 8 × 10 6 A549 in the flank region of 6-week-old BALB/c thymic nude mice 1 × 10 6 MSC-TERT- cells (lung cancer cell line) were subcutaneously transplanted and infected with an oncolytic adenovirus expressing shHSP27-shTGFβ1 by tail vein into 2 mice each having an average tumor size of 150 mm 3 . tetoneE1B55K-GRP78 was injected. And 3 days later, 1 × 10 6 MSC-TERT-tetoneE1B55K-GRP78 infected with an oncolytic adenovirus expressing shHSP27-shTGFβ1 were additionally injected. Then, on the 7th day after the second injection, the tumors of each group of mice were removed and the tumor-sectioned samples were reacted with an adenovirus type 5 specific antibody (Abcam, Cambridge, UK), followed by DAB color reaction with a secondary antibody and immunization with hematoxylin nuclear staining. Counterstaining for histochemistry was performed. At this time, all groups were fed with doxycycline (625 mg/kg) as feed.

그 결과, 아데노바이러스 특이 단백질들은 확인된 대부분의 면적에서 확인되었다(도 34). 아데노바이러스가 최소 꼬리 정맥 주사 후 7일까지는 종양 조직에서 MSC로부터 방출되어 복제, 증식과 퍼짐(spreading)이 반복적으로 일어나고 있음을 보여주며, 종양 크기가 거의 0수준으로 줄어들고 있는 20일 전후까지는 바이러스가 잔존하고 있을 가능성을 확인하였다. As a result, adenovirus-specific proteins were identified in most of the identified areas (FIG. 34). Adenovirus was released from the MSCs from the tumor tissue up to 7 days after the minimal tail vein injection, showing that replication, proliferation and spreading are occurring repeatedly, and the virus was not present until around 20 days when the tumor size was reduced to almost zero level. Possibility of remaining was confirmed.

5) 인간 지방MSC-TERT-tetoneE1B55K-GRP78 세포주 확립- 독시사이클린 1.25㎍/mL 48h 후 E1B55K 발현 여부 확인 5) Human adipose MSC-TERT - Establishment of tetoneE1B55K-GRP78 cell line - Confirmation of E1B55K expression after 48h of doxycycline 1.25㎍/mL

GP2-293 패키징 세포에 pRetroX-TetOne-E1B55K과 막 단백질을 인코딩하는 pAmpho 벡터를 cotransfection하여 얻은 retroviral soup 감염 후 puromycin selection(0.8μg/ml~1.0μg/ml)하고, 다시 플래티눔-A 패키징 세포에 레트로바이러스 벡터인 pLNCXneo-GRP78을 트랜스펙션하여 얻은 retroviral soup 감염 후 G418 selection(500 μg/ml~600μg/ml)하고 독시사이클린 존재 (1.25 μg/ml) 하에 E1B55K 및 MMP2 단백질 발현이 뚜렷한 최종 클론들을 선별하였다 (도 35, 최종 클론 21,24,25,26). After infection with retroviral soup obtained by cotransfection of pRetroX-TetOne-E1B55K and the pAmpho vector encoding the membrane protein into GP2-293 packaging cells, puromycin selection (0.8μg/ml~1.0μg/ml) was performed, and the platinum-A packaging cells were again incubated. After infection with retroviral soup obtained by transfection of pLNCXneo-GRP78, a retroviral vector, G418 selection (500 μg/ml~600 μg/ml) and final clones with clear E1B55K and MMP2 protein expression were selected in the presence of doxycycline (1.25 μg/ml). (Fig. 35, final clone 21,24,25,26).

최종 클론 21번에서 독시사이클린에 의한 E1B55K 유도 농도는 사용하던 1.25 μg/ml의 1/10도 채 안되는 매우 낮은 농도에서도 효과적으로 충분히 누출이 전혀 없이 발현 유도되고 있음을 보여준다 (도 36). 이는 in vivo 에서 발현 유도 물질인 독시사이클린의 처리량에 크게 좌우되지 않고 단지 독시사이클린 존재 유무에 의해서 매우 민감하게 반응하므로 in vivo 에서 on/off를 확실하게 할 수 있어 바이러스의 생산을 원하는 시점에 유도할 수 있게 됨을 시사한다. In the final clone 21, the concentration of E1B55K induced by doxycycline was shown to be effectively induced without leakage even at a very low concentration of less than 1/10 of the used 1.25 μg/ml ( FIG. 36 ). This does not depend greatly on the throughput of doxycycline, which is an expression inducer in vivo, but reacts very sensitively only to the presence or absence of doxycycline. suggests that

인간 지방MSC-TERT-tetoneE1B55K-GRP78 (클론 21번)의 바이러스 생산능은 shHSP27/shTGFβ1 발현하는 종양 살상 아데노바이러스 감염 후 독시사이클린 처리 (1.25 μg/ml) 시 MSC에서 바이러스 생산 증가율을 48 시간 후 확인하였으며, 이때 E4orf6 유전자 발현에 따른 바이러스 생산량 차이도 확인하였다. 이 실험을 위해 클론 21번의 MSC에 E4orf6 유전자가 서브클로닝된 pFlag-CMV2-E4orf6 또는 대조군으로서 pFlag-CMV2를 각각 1 μg씩 트랜스펙션하고 shHSP27/shTGFβ1발현하는 종양 살상 아데노바이러스 추가 감염 후 독시사이클린 처리(1.25 μg/ml 48 h 동안) 한 다음 수확한 soup와 잔존 세포 안의 전체 바이러스 양을 titration 하여 측정하였다. 그 결과, 최종 클론 21번에서 독시사이클린 처리 시 바이러스 생산이 10배 가까이 증가하는 것을 확인하였으며, E4orf6 유전자 트랜스펙션 여부에 따라 바이러스의 생산량에 차이가 나타났다 (도 37). 즉, E4orf6 외부 발현 유도에 따라 바이러스의 생산량이 감소하였다. 이는 E1B55K 단독의 작용에 의한 바이러스 생산 증가를 E4ORF6에 의한 complex 형성으로 인한 바이러스 생산 저해요소로 작용하는 것으로 보인다. (E1B55K 단독에 의한 MSC의 세포사멸과정 유도는 바이러스 생산에 기여함을 확인한 것이다. E1B55K/E4orf6 복합체는 MSC의 세포사멸을 방해하여 결과적으로 바이러스 생산의 최적 시기를 놓치게 한다.)The virus production ability of human adipose MSC-TERT-tetoneE1B55K-GRP78 (clone No. 21) was confirmed after 48 hours of increase in virus production in MSCs treated with doxycycline (1.25 μg/ml) after infection with an oncolytic adenovirus expressing shHSP27/shTGFβ1. , At this time, a difference in virus production according to E4orf6 gene expression was also confirmed. For this experiment, 1 μg of pFlag-CMV2-E4orf6 subcloned with the E4orf6 gene or pFlag-CMV2 as a control were transfected into MSC of clone 21 for this experiment. After additional infection with oncolytic adenovirus expressing shHSP27/shTGFβ1, doxycycline treatment ( 1.25 μg/ml for 48 h), and then titration was performed on the total amount of virus in the harvested soup and remaining cells. As a result, it was confirmed that the virus production increased nearly 10-fold upon treatment with doxycycline in the final clone 21, and there was a difference in virus production depending on whether the E4orf6 gene was transfected (FIG. 37). That is, the virus production was reduced according to the induction of E4orf6 exogenous expression. It seems that the increase in virus production caused by the action of E1B55K alone acts as a factor inhibiting virus production due to the complex formation by E4ORF6. (It was confirmed that the induction of MSC apoptosis process by E1B55K alone contributes to virus production. The E1B55K/E4orf6 complex interferes with MSC apoptosis and consequently misses the optimal time for virus production.)

6) 인간 지방 MSC-TERT low passage와 high passage에서의 효능 유지 비교6) Human fat MSC-TERT comparison of efficacy maintenance in low passage and high passage

master cell bank 세포주 200 vial 이상 대량 생산 시 MSC 효능 유지 확인이 필수적이다. 즉, 최종 MSC-TERT-tetoneE1B55K-GRP78의 계대별 차이로 인한 MSC 특성인 tumor homing에 관련된 마커들로 알려진 바이오마커들의 유지 여부를 low passage (p13)과 high passage (p23)에서 획득한 세포 각각을 용해시킨 샘플로부터 웨스턴 블랏팅으로 확인하였다. When mass-producing more than 200 vials of the master cell bank cell line, it is essential to confirm the maintenance of MSC efficacy. In other words, whether or not biomarkers known as markers related to tumor homing, which is a characteristic of MSC due to the difference by passage of the final MSC-TERT-tetoneE1B55K-GRP78, are maintained, each of the cells obtained at low passage (p13) and high passage (p23) It was confirmed by Western blotting from the lysed sample.

그 결과, passage가 20으로 증가하여도 tumor homing marker로 알려진 단백질들의 발현에는 차이가 없는 것을 확인하였다(도 38).As a result, it was confirmed that there was no difference in the expression of proteins known as tumor homing markers even when passage was increased to 20 (FIG. 38).

실시예 4: MSC-TERT-tetoneE1B55K-GRP78에 감염된 종양 살상 아데노바이러스의 항암 효능 Example 4: Anticancer efficacy of oncolytic adenovirus infected with MSC-TERT-tetoneE1B55K-GRP78

6주령의 BALB/c 흉선 누드 마우스의 옆구리 부위에 8 × 106 개의 A549 세포 (폐암 세포주) 피하에 이식하고 종양 크기가 평균 150 mm3에 도달한 마우스들을 각각 10마리씩 그룹 분리하였다. 마우스 꼬리 정맥으로 shHSP27-shTGFβ1을 발현하는 종양 살상 아데노바이러스가 감염된 1 × 106 개의 MSC-TERT-tetoneE1B55K-GRP78을 주사하였다. 그리고 3일이 지난 후에 추가로 shHSP27-shTGFβ1을 발현하는 종양 살상 아데노바이러스가 감염된 1 × 106 개의 MSC-TERT-tetoneE1B55K-GRP78을 정맥 주사하였다. 대조군으로는 종양 세포만 이식한 그룹(no treat)과 최종 MSC-TERT-tetoneE1B55K-GRP78를 주입한 그룹(MSC only)을 사용하였다. 이때 모든 그룹에 독시사이클린 (625 mg/kg)이 포함된 먹이를 사료로 공급하였다. 8 × 10 6 A549 in the flank region of 6-week-old BALB/c thymic nude mice Cells (lung cancer cell line) were subcutaneously transplanted and the mice having an average tumor size of 150 mm 3 were separated into groups of 10 each. Mice were injected with 1 × 10 6 MSC-TERT-tetoneE1B55K-GRP78 infected with an oncolytic adenovirus expressing shHSP27-shTGFβ1 into the tail vein. And after 3 days, 1 × 10 6 MSC-TERT-tetoneE1B55K-GRP78 infected with an oncolytic adenovirus expressing shHSP27-shTGFβ1 were additionally injected intravenously. As a control group, a group transplanted with only tumor cells (no treat) and a group injected with the final MSC-TERT-tetoneE1B55K-GRP78 (MSC only) were used. At this time, all groups were fed with doxycycline (625 mg/kg) as feed.

그 결과, 종양 살상 바이러스 (Ad-3484-shHSP27-shTGFβ1)를 종양 내 직접 주사 시 얻은 항종양 효과 (대조군에 비하여 종양 크기 성장속도는 지연되었으나 종양 크기 자체가 감소되어 회귀되지는 못한 상태) 비교했을 때 도 39 에서 보듯이 아무것도 처리하지 않은 종양이나 최종 타입의 MSC 만을 꼬리 정맥으로 주사한 대조군에 비하여 최종 MSC-TERT-tetoneE1B55K-GRP78에 종양 살상 바이러스 (Ad-3484-shHSP27-shTGFβ1)를 꼬리 정맥 주사하였을 때 몇 일 사이에 종양 크기가 현저히 줄어들어 거의 사라지는 것을 관찰하였으며 주사 후 20여일동안 종양은 거의 사라졌으며 그 이후 다시 몇몇 개체에서 종양이 약간씩 자라는 것을 알 수 있었다. 처음 OV/MSC 주사 후 한 달이 지난 후에 각 군별 마우스들의 개체 사진과 종양을 적출하고 나서 각 군별 찍은 적출된 종양 사진을 통하여 보다 확실히 최종 MSC-TERT-tetoneE1B55K-GRP78에 종양 살상 바이러스 (Ad-3484-shHSP27-shTGFβ1)에 의한 항종양 효과를 확인할 수 있었다 (도 40). As a result, the antitumor effect obtained when the oncolytic virus (Ad-3484-shHSP27-shTGFβ1) was injected directly into the tumor (the tumor size growth rate was delayed compared to the control group, but the tumor size itself decreased and did not return) As shown in FIG. 39, tail vein injection of an oncolytic virus (Ad-3484-shHSP27-shTGFβ1) into the final MSC-TERT-tetoneE1B55K-GRP78 compared to the control group injected with either an untreated tumor or only the final type of MSC via tail vein. It was observed that the tumor size was significantly reduced within a few days and almost disappeared. After 20 days after injection, the tumor almost disappeared, and after that, it was found that the tumor grew slightly again in some individuals. One month after the initial OV/MSC injection, the final MSC-TERT-tetoneE1B55K-GRP78 oncolytic virus (Ad-3484) -shHSP27-shTGFβ1) was able to confirm the antitumor effect (FIG. 40).

실시예 5: 종양 외 다른 장기로의 흡착 확인Example 5: Confirmation of adsorption to organs other than tumors

종양 타겟팅은 매우 효율적으로 일어나고 있음을 확인 후 종양 이외 주요 장기 (폐, 간, 비장 등)에 포획된 양 그리고 종양 부위로의 이동 및 경과시간 등을 보다 자세하게 확인하기 위하여 종양을 포함한 주요 장기별 바이러스 양을 시간대별로 아데노바이러스 유전자 카피 수를 측정하였다. viral genomic 플라스미드 DNA를 standard 기지의 DNA로 정하여 standard curve를 그려 확인하였다 (현재 사용한 종양 살상 아데노바이러스의 viral DNA의 경우 1 copy 가 103 pg 임). After confirming that tumor targeting is occurring very efficiently, viruses by major organs including tumors can be identified in more detail, such as the amount captured in major organs (lung, liver, spleen, etc.) The amount of adenovirus gene copy number was measured over time. The viral genomic plasmid DNA was determined as the standard DNA and a standard curve was drawn to confirm (1 copy of the currently used oncolytic adenovirus viral DNA is 10 3 pg).

이를 위하여 복제 불능 defectvie E1B55K 바이러스 감염시킨 후 다시 참조예 1의 YSC-02 종양 살상 바이러스가 감염된 MSC-TERT-GRP78 (1 × 106)를 꼬리로 IV 단회 투여를 진행하고 날짜별 (0, 1, 2, 3, 4, 5, 10, 15일)로 샘플을 채취하였다. 채취한 조직 (종양, 폐, 간, 비장, 신장, 심장)은 바로 액체 질소에 보관하고 조직 샘플링이 끝나는 날에 같은 조건하에 조직별 genomic DNA를 추출하였다. 추출된 genomic DNA를 이용하여 유전자 발현 유무를 확인하기 위하여 E4ORF 유전자의 프라이머를 사용하여 실시간 PCR을 진행하였다. 이때 사용된 E4 ORF 스크린용 프라이머는 다음과 같다. To this end, after infection with the replication-incompetent defectvie E1B55K virus, MSC-TERT-GRP78 (1 × 10 6 ) infected with the YSC-02 oncolytic virus of Reference Example 1 was administered as a single IV administration by tail, and each day (0, 1, 2, 3, 4, 5, 10, 15). The collected tissues (tumor, lung, liver, spleen, kidney, heart) were immediately stored in liquid nitrogen, and genomic DNA for each tissue was extracted under the same conditions on the day the tissue sampling was finished. Real-time PCR was performed using the primers of the E4ORF gene to check the presence or absence of gene expression using the extracted genomic DNA. The primers for the E4 ORF screen used at this time are as follows.

Forward 5'-CGTGGTCAAACT CTACAGCC-3': 서열번호 20Forward 5'-CGTGGTCAAACT CTACAGCC-3': SEQ ID NO: 20

Reverse 5'-GCATGAGCATGACTACGATG-3': 서열번호 21Reverse 5'-GCATGAGCATGACTACGATG-3': SEQ ID NO: 21

도 41에서 볼 수 있듯이, 개체간 variation이 심하나 종양 조직에서 종양 살상 바이러스가 들어간 경우의 개체 조직에서는 그 범위가 104 ~ 1010 copy 로 다른 모든 장기에서 발견되는 copy 수 ~ 10 개에 비하면, 거의 모든 바이러스가 흡착, 흡수되는 곳은 종양조직임을 알 수 있다.As can be seen in FIG. 41 , although the variation between individuals is severe, the range is 10 4 to 10 10 copies in the individual tissue when the oncolytic virus is contained in the tumor tissue, compared to the number of copies found in all other organs ~ 10, almost It can be seen that the place where all viruses are adsorbed and absorbed is the tumor tissue.

<110> Industry-Academic Cooperation Foundation, Yonsei University <120> Mesenchymal stem cells capable of improving tumor targeting and mass production of viruses <130> P21U18C1147 <150> KR 10-2020-0139918 <151> 2020-10-27 <160> 31 <170> KoPatentIn 3.0 <210> 1 <211> 1965 <212> DNA <213> Homo sapiens <400> 1 atgaagctct ccctggtggc cgcgatgctg ctgctgctca gcgcggcgcg ggccgaggag 60 gaggacaaga aggaggacgt gggcacggtg gtcggcatcg acctggggac cacctactcc 120 tgcgtcggcg tgttcaagaa cggccgcgtg gagatcatcg ccaacgatca gggcaaccgc 180 atcacgccgt cctatgtcgc cttcactcct gaaggggaac gtctgattgg cgatgccgcc 240 aagaaccagc tcacctccaa ccccgagaac acggtctttg acgccaagcg gctcatcggc 300 cgcacgtgga atgacccgtc tgtgcagcag gacatcaagt tcttgccgtt caaggtggtt 360 gaaaagaaaa ctaaaccata cattcaagtt gatattggag gtgggcaaac aaagacattt 420 gctcctgaag aaatttctgc catggttctc actaaaatga aagaaaccgc tgaggcttat 480 ttgggaaaga aggttaccca tgcagttgtt actgtaccag cctattttaa tgatgcccaa 540 cgccaagcaa ccaaagacgc tggaactatt gctggcctaa atgttatgag gatcatcaac 600 gagcctacgg cagctgctat tgcttatggc ctggataaga gggaggggga gaagaacatc 660 ctggtgtttg acctgggtgg cggaaccttc gatgtgtctc ttctcaccat tgacaatggt 720 gtcttcgaag ttgtggccac taatggagat actcatctgg gtggagaaga ctttgaccag 780 cgtgtcatgg aacacttcat caaactgtac aaaaagaaga cgggcaaaga tgtcaggaaa 840 gacaatagag ctgtgcagaa actccggcgc gaggtagaaa aggccaaacg ggccctgtct 900 tctcagcatc aagcaagaat tgaaattgag tccttctatg aaggagaaga cttttctgag 960 accctgactc gggccaaatt tgaagagctc aacatggatc tgttccggtc tactatgaag 1020 cccgtccaga aagtgttgga agattctgat ttgaagaagt ctgatattga tgaaattgtt 1080 cttgttggtg gctcgactcg aattccaaag attcagcaac tggttaaaga gttcttcaat 1140 ggcaaggaac catcccgtgg cataaaccca gatgaagctg tagcgtatgg tgctgctgtc 1200 caggctggtg tgctctctgg tgatcaagat acaggtgacc tggtactgct tgatgtatgt 1260 ccccttacac ttggtattga aactgtggga ggtgtcatga ccaaactgat tccaaggaac 1320 acagtggtgc ctaccaagaa gtctcagatc ttttctacag cttctgataa tcaaccaact 1380 gttacaatca aggtctatga aggtgaaaga cccctgacaa aagacaatca tcttctgggt 1440 acatttgatc tgactggaat tcctcctgct cctcgtgggg tcccacagat tgaagtcacc 1500 tttgagatag atgtgaatgg tattcttcga gtgacagctg aagacaaggg tacagggaac 1560 aaaaataaga tcacaatcac caatgaccag aatcgcctga cacctgaaga aatcgaaagg 1620 atggttaatg atgctgagaa gtttgctgag gaagacaaaa agctcaagga gcgcattgat 1680 actagaaatg agttggaaag ctatgcctat tctctaaaga atcagattgg agataaagaa 1740 aagctgggag gtaaactttc ctctgaagat aaggagacca tggaaaaagc tgtagaagaa 1800 aagattgaat ggctggaaag ccaccaagat gctgacattg aagacttcaa agctaagaag 1860 aaggaactgg aagaaattgt tcaaccaatt atcagcaaac tctatggaag tgcaggccct 1920 cccccaactg gtgaagagga tacagcagaa aaagatgagt tgtag 1965 <210> 2 <211> 3399 <212> DNA <213> Homo sapiens <400> 2 atgccgcgcg ctccccgctg ccgagccgtg cgctccctgc tgcgcagcca ctaccgcgag 60 gtgctgccgc tggccacgtt cgtgcggcgc ctggggcccc agggctggcg gctggtgcag 120 cgcggggacc cggcggcttt ccgcgcgctg gtggcccagt gcctggtgtg cgtgccctgg 180 gacgcacggc cgccccccgc cgccccctcc ttccgccagg tgtcctgcct gaaggagctg 240 gtggcccgag tgctgcagag gctgtgcgag cgcggcgcga agaacgtgct ggccttcggc 300 ttcgcgctgc tggacggggc ccgcgggggc ccccccgagg ccttcaccac cagcgtgcgc 360 agctacctgc ccaacacggt gaccgacgca ctgcggggga gcggggcgtg ggggctgctg 420 ctgcgccgcg tgggcgacga cgtgctggtt cacctgctgg cacgctgcgc gctctttgtg 480 ctggtggctc ccagctgcgc ctaccaggtg tgcgggccgc cgctgtacca gctcggcgct 540 gccactcagg cccggccccc gccacacgct agtggacccc gaaggcgtct gggatgcgaa 600 cgggcctgga accatagcgt cagggaggcc ggggtccccc tgggcctgcc agccccgggt 660 gcgaggaggc gcgggggcag tgccagccga agtctgccgt tgcccaagag gcccaggcgt 720 ggcgctgccc ctgagccgga gcggacgccc gttgggcagg ggtcctgggc ccacccgggc 780 aggacgcgtg gaccgagtga ccgtggtttc tgtgtggtgt cacctgccag acccgccgaa 840 gaagccacct ctttggaggg tgcgctctct ggcacgcgcc actcccaccc atccgtgggc 900 cgccagcacc acgcgggccc cccatccaca tcgcggccac cacgtccctg ggacacgcct 960 tgtcccccgg tgtacgccga gaccaagcac ttcctctact cctcaggcga caaggagcag 1020 ctgcggccct ccttcctact cagctctctg aggcccagcc tgactggcgc tcggaggctc 1080 gtggagacca tctttctggg ttccaggccc tggatgccag ggactccccg caggttgccc 1140 cgcctgcccc agcgctactg gcaaatgcgg cccctgtttc tggagctgct tgggaaccac 1200 gcgcagtgcc cctacggggt gctcctcaag acgcactgcc cgctgcgagc tgcggtcacc 1260 ccagcagccg gtgtctgtgc ccgggagaag ccccagggct ctgtggcggc ccccgaggag 1320 gaggacacag acccccgtcg cctggtgcag ctgctccgcc agcacagcag cccctggcag 1380 gtgtacggct tcgtgcgggc ctgcctgcgc cggctggtgc ccccaggcct ctggggctcc 1440 aggcacaacg aacgccgctt cctcaggaac accaagaagt tcatctccct ggggaagcat 1500 gccaagctct cgctgcagga gctgacgtgg aagatgagcg tgcgggactg cgcttggctg 1560 cgcaggagcc caggggttgg ctgtgttccg gccgcagagc accgtctgcg tgaggagatc 1620 ctggccaagt tcctgcactg gctgatgagt gtgtacgtcg tcgagctgct caggtctttc 1680 ttttatgtca cggagaccac gtttcaaaag aacaggctct ttttctaccg gaagagtgtc 1740 tggagcaagt tgcaaagcat tggaatcaga cagcacttga agagggtgca gctgcgggag 1800 ctgtcggaag cagaggtcag gcagcatcgg gaagccaggc ccgccctgct gacgtccaga 1860 ctccgcttca tccccaagcc tgacgggctg cggccgattg tgaacatgga ctacgtcgtg 1920 ggagccagaa cgttccgcag agaaaagagg gccgagcgtc tcacctcgag ggtgaaggca 1980 ctgttcagcg tgctcaacta cgagcgggcg cggcgccccg gcctcctggg cgcctctgtg 2040 ctgggcctgg acgatatcca cagggcctgg cgcaccttcg tgctgcgtgt gcgggcccag 2100 gacccgccgc ctgagctgta ctttgtcaag gtggatgtga cgggcgcgta cgacaccatc 2160 ccccaggaca ggctcacgga ggtcatcgcc agcatcatca aaccccagaa cacgtactgc 2220 gtgcgtcggt atgccgtggt ccagaaggcc gcccatgggc acgtccgcaa ggccttcaag 2280 agccacgtct ctaccttgac agacctccag ccgtacatgc gacagttcgt ggctcacctg 2340 caggagacca gcccgctgag ggatgccgtc gtcatcgagc agagctcctc cctgaatgag 2400 gccagcagtg gcctcttcga cgtcttccta cgcttcatgt gccaccacgc cgtgcgcatc 2460 aggggcaagt cctacgtcca gtgccagggg atcccgcagg gctccatcct ctccacgctg 2520 ctctgcagcc tgtgctacgg cgacatggag aacaagctgt ttgcggggat tcggcgggac 2580 gggctgctcc tgcgtttggt ggatgatttc ttgttggtga cacctcacct cacccacgcg 2640 aaaaccttcc tcaggaccct ggtccgaggt gtccctgagt atggctgcgt ggtgaacttg 2700 cggaagacag tggtgaactt ccctgtagaa gacgaggccc tgggtggcac ggcttttgtt 2760 cagatgccgg cccacggcct attcccctgg tgcggcctgc tgctggatac ccggaccctg 2820 gaggtgcaga gcgactactc cagctatgcc cggacctcca tcagagccag tctcaccttc 2880 aaccgcggct tcaaggctgg gaggaacatg cgtcgcaaac tctttggggt cttgcggctg 2940 aagtgtcaca gcctgtttct ggatttgcag gtgaacagcc tccagacggt gtgcaccaac 3000 atctacaaga tcctcctgct gcaggcgtac aggtttcacg catgtgtgct gcagctccca 3060 tttcatcagc aagtttggaa gaaccccaca tttttcctgc gcgtcatctc tgacacggcc 3120 tccctctgct actccatcct gaaagccaag aacgcaggga tgtcgctggg ggccaagggc 3180 gccgccggcc ctctgccctc cgaggccgtg cagtggctgt gccaccaagc attcctgctc 3240 aagctgactc gacaccgtgt cacctacgtg ccactcctgg ggtcactcag gacagcccag 3300 acgcagctga gtcggaagct cccggggacg acgctgactg ccctggaggc cgcagccaac 3360 ccggcactgc cctcagactt caagaccatc ctggactga 3399 <210> 3 <211> 1491 <212> DNA <213> Human adenovirus type 5 <400> 3 atggagcgaa gaaacccatc tgagcgggga gtacctgctg gattttctgg ccatgcatct 60 gtggagagcg gttgtgagac acaagaatcg cctgctactg ttgtcttccg tccgcccggc 120 gataataccg acggaggagc agcagcagca gcaggaggaa gccaggcggc ggcggcagga 180 gcagagccca tggaacccga gagccggcct ggaccctcgg gaatgaatgt tgtacaggtg 240 gctgaactgt atccagaact gagacgcatt ttgacaatta cagaggatgg gcaggggcta 300 aagggggtaa agagggagcg gggggcttgt gaggctacag aggaggctag gaatctagct 360 tttagcttaa tgaccagaca ccgtcctgag tgtattactt ttcaacagat caaggataat 420 tgcgctaatg agcttgatct gctggcgcag aagtattcca tagagcagct gaccacttac 480 tggctgcagc caggggatga ttttgaggag gctattaggg tatatgcaaa ggtggcactt 540 aggccagatt gcaagtacaa gatcagcaaa cttgtaaata tcaggaattg ttgctacatt 600 tctgggaacg gggccgaggt ggagatagat acggaggata gggtggcctt tagatgtagc 660 atgataaata tgtggccggg ggtgcttggc atggacgggg tggttattat gaatgtaagg 720 tttactggcc ccaattttag cggtacggtt ttcctggcca ataccaacct tatcctacac 780 ggtgttagct tctatgggtt taacaatacc tgtgtggaag cctggaccga tgtaagggtt 840 cggggctgtg ccttttactg ctgctggaag ggggtggtgt gtcgccccaa aagcagggct 900 tcaattaaga aatgcctctt tgaaaggtgt accttgggta tcctgtctga gggtaactcc 960 agggtgcgcc acaatgtggc ctccgactgt ggttgcttca tgctagtgaa aagcgtggct 1020 gtgattaagc ataacatggt atgtggcaac tgcgaggaca gggcctctca gatgctgacc 1080 tgctcggacg gcaactgtca cctgctgaag accattcacg tagccagcca ctctcgcaag 1140 gcctggccag tgtttgagca taacatactg acccgctgtt ccttgcattt gggtaacagg 1200 aggggggtgt tcctacctta ccaatgcaat ttgagtcaca ctaagatatt gcttgagccc 1260 gagagcatgt ccaaggtgaa cctgaacggg gtgtttgaca tgaccatgaa gatctggaag 1320 gtgctgaggt acgatgagac ccgcaccagg tgcagaccct gcgagtgtgg cggtaaacat 1380 attaggaacc agcctgtgat gctggatgtg accgaggagc tgaggcccga tcacttggtg 1440 ctggcctgca cccgcgctga gtttggctct agcgatgaag atacagattg a 1491 <210> 4 <211> 29 <212> DNA <213> Artificial Sequence <220> <223> BamHI/NotI forward primer <400> 4 gcggatccat ggagcgaaga aacccatct 29 <210> 5 <211> 28 <212> DNA <213> Artificial Sequence <220> <223> BamHI/NotI reverse primer <400> 5 cggccgctca atctgtatct tcatcgct 28 <210> 6 <211> 30 <212> DNA <213> Artificial Sequence <220> <223> HindIII forward primer <400> 6 gtacaagctt atgactacgt ccggcgttcc 30 <210> 7 <211> 30 <212> DNA <213> Artificial Sequence <220> <223> XbaI reverse primer <400> 7 cacctctaga ctacatgggg gtagagtcat 30 <210> 8 <211> 30 <212> DNA <213> Artificial Sequence <220> <223> CMV30 <400> 8 aatgtcgtaa taaccccgcc ccgttgacgc 30 <210> 9 <211> 30 <212> DNA <213> Artificial Sequence <220> <223> XbaI sense primer <400> 9 ttcatctaga atggagcgaa gaaacccatc 30 <210> 10 <211> 30 <212> DNA <213> Artificial Sequence <220> <223> HindIII antisense primer <400> 10 gacgaagctt tcaatctgta tcttcatcgc 30 <210> 11 <211> 25 <212> DNA <213> Artificial Sequence <220> <223> hCMV forward primer <400> 11 gggaggtcta tataagcaga gctcg 25 <210> 12 <211> 25 <212> DNA <213> Artificial Sequence <220> <223> pCA14 SV40 reverse primer <400> 12 catgatcgat gctagacgat ccaga 25 <210> 13 <211> 25 <212> PRT <213> Artificial Sequence <220> <223> N terminus of E1B55K <400> 13 Met Glu Arg Arg Asn Pro Ser Glu Arg Gly Val Pro Ala Gly Phe Ser 1 5 10 15 Gly His Ala Ser Val Glu Ser Gly Cys 20 25 <210> 14 <211> 40 <212> DNA <213> Artificial Sequence <220> <223> E1B55K In-fusion EcoRI sense primer <400> 14 ccctcgtaaa gaattcatgg agcgaagaaa cccatctgag 40 <210> 15 <211> 40 <212> DNA <213> Artificial Sequence <220> <223> E1B55K In-fusion BamHI antisense primer <400> 15 gaggtggtct ggatcctcaa tctgtatctt catcgctaga 40 <210> 16 <211> 26 <212> DNA <213> Artificial Sequence <220> <223> XbaI Forward primer <400> 16 gattctcgag atgaagctct ccctgg 26 <210> 17 <211> 26 <212> DNA <213> Artificial Sequence <220> <223> XbaI Reverse primer <400> 17 ggcctctaga ctacaactca tctttt 26 <210> 18 <211> 62 <212> DNA <213> Artificial Sequence <220> <223> pLNCX neo Top strand <400> 18 agcttcacgt gccagcacag tggcggccgc tcgagtcgac gggcccgttt aaacgttaac 60 at 62 <210> 19 <211> 60 <212> DNA <213> Artificial Sequence <220> <223> pLNCX neo Bottom strand <400> 19 cgatgttaac gtttaaacgg gcccgtcgac tcgagcggcc gccactgtgc tggcacgtga 60 60 <210> 20 <211> 20 <212> DNA <213> Artificial Sequence <220> <223> E4 ORF Forward primer <400> 20 cgtggtcaaa ctctacagcc 20 <210> 21 <211> 20 <212> DNA <213> Artificial Sequence <220> <223> E4 ORF Reverse primer <400> 21 gcatgagcat gactacgatg 20 <210> 22 <211> 912 <212> DNA <213> Artificial Sequence <220> <223> Flag-E4orf6 <400> 22 gactacaaag acgatgacga caagcttatg actacgtccg gcgttccatt tggcatgaca 60 ctacgaccaa cacgatctcg gttgtctcgg cgcactccgt acagtaggga tcgtctacct 120 ccttttgaga cagaaacccg cgctaccata ctggaggatc atccgctgct gcccgaatgt 180 aacactttga caatgcacaa cgtgagttac gtgcgaggtc ttccctgcag tgtgggattt 240 acgctgattc aggaatgggt tgttccctgg gatatggttc taacgcggga ggagcttgta 300 atcctgagga agtgtatgca cgtgtgcctg tgttgtgcca acattgatat catgacgagc 360 atgatgatcc atggttacga gtcctgggct ctccactgtc attgttccag tcccggttcc 420 ctgcagtgta tagccggcgg gcaggttttg gccagctggt ttaggatggt ggtggatggc 480 gccatgttta atcagaggtt tatatggtac cgggaggtgg tgaattacaa catgccaaaa 540 gaggtaatgt ttatgtccag cgtgtttatg aggggtcgcc acttaatcta cctgcgcttg 600 tggtatgatg gccacgtggg ttctgtggtc cccgccatga gctttggata cagcgccttg 660 cactgtggga ttttgaacaa tattgtggtg ctgtgctgca gttactgtgc tgatttaagt 720 gagatcaggg tgcgctgctg tgcccggagg acaaggcgcc ttatgctgcg ggcggtgcga 780 atcatcgctg aggagaccac tgccatgttg tattcctgca ggacggagcg gcggcggcag 840 cagtttattc gcgcgctgct gcagcaccac cgccctatcc tgatgcacga ttatgactct 900 acccccatgt ag 912 <210> 23 <211> 1196 <212> DNA <213> Artificial Sequence <220> <223> sample 2-Fig. 7 <400> 23 aaccgtcaga attgatctac catggactac aaagacgatg acgacaagct tatgactacg 60 tccggcgttc catttggcat gacactacga ccaacacgat ctcggttgtc tcggcgcact 120 ccgtacagta gggatcgtct acctcctttt gagacagaaa cccgcgctac catactggag 180 gatcatccgc tgctgcccga atgtaacact ttgacaatgc acaacgtgag ttacgtgcga 240 ggtcttccct gcagtgtggg atttacgctg attcaggaat gggttgttcc ctgggatatg 300 gttctaacgc gggaggagct tgtaatcctg aggaagtgta tgcacgtgtg cctgtgttgt 360 gccaacattg atatcatgac gagcatgatg atccatggtt acgagtcctg ggctctccac 420 tgtcattgtt ccagtcccgg ttccctgcag tgtatagccg gcgggcaggt tttggccagc 480 tggtttagga tggtggtgga tggcgccatg tttaatcaga ggtttatatg gtaccgggag 540 gtggtgaatt acaacatgcc aaaagaggta atgtttatgt ccagcgtgtt tatgaggggt 600 cgccacttaa tctacctgcg cttgtggtat gatggccacg tgggttctgt ggtccccgcc 660 atgagctttg gatacagcgc cttgcactgt gggattttga acaatattgt ggtgctgtgc 720 tgcagttact gtgctgattt aagtgagatc agggtgcgct gctgtgcccg gaggacaagg 780 cgccttatgc tgcgggcggt gcgaatcatc gctgaggaga ccactgccat gttgtattcc 840 tgcaggacgg agcggcggcg gcagcagttt attcgcgcgc tgctgcagca ccaccgccct 900 atcctgatgc acgattatga ctctaccccc atgtagtcta gaggatcccg ggtggcatcc 960 ctgtgacccc tccccagtgc ctctcctggc cctggaagtt gccactccag tgcccaccag 1020 ccttgtccta ataaaattaa gttgcatcat tttgtctgac taggtgtcct tctataatat 1080 tatggggtgg aggggggggg tatggaacca aggggcaagt tgggaaaaaa acctgaaggg 1140 cctgcgggtc ttattgggaa ccaaactggg agtgcagtgg accaattttg ggttcc 1196 <210> 24 <211> 960 <212> DNA <213> Artificial Sequence <220> <223> pCA14-E1B55K forward <400> 24 aagacaccgg gaccgatcca gcctggggat cttcgagtcg agggatccct cgagtctaga 60 atggagcgaa gaaacccatc tgagcgggga gtacctgctg gattttctgg ccatgcatct 120 gtggagagcg gttgtgagac acaagaatcg cctgctactg ttgtcttccg tccgcccggc 180 gataataccg acggaggagc agcagcagca gcaggaggaa gccaggcggc ggcggcagga 240 gcagagccca tggaacccga gagccggcct ggaccctcgg gaatgaatgt tgtacaggtg 300 gctgaactgt atccagaact gagacgcatt ttgacaatta cagaggatgg gcaggggcta 360 aagggggtaa agagggagcg gggggcttgt gaggctacag aggaggctag gaatctagct 420 tttagcttaa tgaccagaca ccgtcctgag tgtattactt ttcaacagat caaggataat 480 tgcgctaatg agcttgatct gctggcgcag aagtattcca tagagcagct gaccacttac 540 tggctgcagc caggggatga ttttgaggag gctattaggg tatatgcaaa ggtggcactt 600 aggccagatt gcaagtacaa gatcagcaaa cttgtaaata tcaggaattg ttgctacatt 660 tctgggaacg gggccgaggt ggagatagat acggaggata gggtggcctt tagatgtagc 720 atgataaata tgtggccggg ggtgcttggc atggacgggg tggttattat gaatgtaagg 780 tttactggcc ccaattttag cggtacggtt ttcctggcca ataccaacct tatcctacac 840 ggtgttagct tctatgggtt taacaatacc tgtgtggaag cctggaccga tgtaagggtt 900 cggggctgtg ccttttactg ctgctggaag ggggtggtgt gtcgccccaa aagcagggct 960 960 <210> 25 <211> 1017 <212> DNA <213> Artificial Sequence <220> <223> pCA14-E1B55K-reverse <400> 25 tttggtccaa ccggggatga tttgaggggg cttttgggtt tttgcaaagg tgcccttagg 60 ccagattgca attacaaaat cagcaaactt gtaaatttca ggaattgttg ctacatttct 120 gggaacgggg ccgaggtgga gatagatacg gaggataggg tggcctttag atgtagcatg 180 ataaatatgt ggccgggggt gcttggcatg gacggggtgg ttattatgaa tgtaaggttt 240 actggcccca attttagcgg tacggttttc ctggccaata ccaaccttat cctacacggt 300 gttagcttct atgggtttaa caatacctgt gtggaagcct ggaccgatgt aagggttcgg 360 ggctgtgcct tttactgctg ctggaagggg gtggtgtgtc gccccaaaag cagggcttca 420 attaagaaat gcctctttga aaggtgtacc ttgggtatcc tgtctgaggg taactccagg 480 gtgcgccaca atgtggcctc cgactgtggt tgcttcatgc tagtgaaaag cgtggctgtg 540 attaagcata acatggtatg tggcaactgc gaggacaggg cctctcagat gctgacctgc 600 tcggacggca actgtcacct gctgaagacc attcacgtag ccagccactc tcgcaaggcc 660 tggccagtgt ttgagcataa catactgacc cgctgttcct tgcatttggg taacaggagg 720 ggggtgttcc taccttacca atgcaatttg agtcacacta agatattgct tgagcccgag 780 agcatgtcca aggtgaacct gaacggggtg tttgacatga ccatgaagat ctggaaggtg 840 ctgaggtacg atgagacccg caccaggtgc agaccctgcg agtgtggcgg taaacatatt 900 aggaaccagc ctgtgatgct ggatgtgacc gaggagctga ggcccgatca cttggtgctg 960 gcctgcaccc gcgctgagtt tggctctagc gatgaagata cagattgaaa gcttgtc 1017 <210> 26 <211> 1172 <212> DNA <213> Artificial Sequence <220> <223> primer E1B55K In-fusion EcoRI sense <400> 26 ccggggggca gtacctgctg gattctctgg ccatgcatct gtggagagcg gttgtgagac 60 acaagaatcg cctgctactg ttgtcttccg tccgcccggc gataataccg acggaggagc 120 agcagcagca gcaggaggaa gccaggcggc ggcggcagga gcagagccca tggaacccga 180 gagccggcct ggaccctcgg gaatgaatgt tgtacaggtg gctgaactgt atccagaact 240 gagacgcatt ttgacaatta cagaggatgg gcaggggcta aagggggtaa agagggagcg 300 gggggcttgt gaggctacag aggaggctag gaatctagct tttagcttaa tgaccagaca 360 ccgtcctgag tgtattactt ttcaacagat caaggataat tgcgctaatg agcttgatct 420 gctggcgcag aagtattcca tagagcagct gaccacttac tggctgcagc caggggatga 480 ttttgaggag gctattaggg tatatgcaaa ggtggcactt aggccagatt gcaagtacaa 540 gatcagcaaa cttgtaaata tcaggaattg ttgctacatc tctgggaacg gggccgaggt 600 ggagatagat acggaggata gggtggcctt tagatgtagc atgataaata tgtggccggg 660 ggtgcttggc atggacgggg tggttattat gaatgtaagg tttactggcc ccaattttag 720 cggtacggtt ttcctggcca ataccaacct tatcctacac ggtgttagct tctatgggtt 780 taacaatacc tgtgtggaag cctggaccga tgtaagggtt cggggctgtg ccttttactg 840 ctgctggaag ggggtggtgt gtcgccccaa aagcagggct tcaattaaga aatgcctctt 900 tgaaaggtgt accttgggta tcctgtctga gggtaactcc agggtgcgcc acaatgtggc 960 ctccgactgt ggttgcttca tgctagtgaa aagcgtggct gtgattaagc ataacatggt 1020 atgtggcaac tgcgaggaca gggcctctca gatgctgacc tgctcggacg gcaactgtca 1080 cctgctgaag acattcacgt agccagccct ttcgcaaggc tggccagggt tgagcatacc 1140 tactgacccc ctgttccttg ctttgggaaa aa 1172 <210> 27 <211> 686 <212> DNA <213> Artificial Sequence <220> <223> primer: E1B55K internal primer <400> 27 acctgtaatt tgtttatttg ggcgtaggtc gggcgtgctt ttactgctgc tggaaggggg 60 tggtgtgtcg ccccaaaagc agggcttcaa ttaagaaatg cctctttgaa aggtgtacct 120 tgggtatcct gtctgagggt aactccaggg tgcgccacaa tgtggcctcc gactgtggtt 180 gcttcatgct agtgaaaagc gtggctgtga ttaagcataa catggtatgt ggcaactgcg 240 aggacagggc ctctcagatg ctgacctgct cggacggcaa ctgtcacctg ctgaagacca 300 ttcacgtagc cagccactct cgcaaggcct ggccagtgtt tgagcataac atactgaccc 360 gctgttcctt gcatttgggt aacaggaggg gggtgttcct accttaccaa tgcaatttga 420 gtcacactaa gatattgctt gagcccgaga gcatgtccaa ggtgaacctg aacggggtgt 480 ttgacatgac catgaagatc tggaaggtgc tgaggtacga tgagacccgc accaggtgca 540 gaccctgcga gtgtggcggt aaacatatta ggaaccagcc tgtgatgctg gatgtgaccg 600 aggagctgag gcccgatcac ttggtgctgg cctgcacccg cgctgagttt ggctctagcg 660 atgaagatac agattgagga tccaga 686 <210> 28 <211> 483 <212> DNA <213> Artificial Sequence <220> <223> E1B55K 5' near internal reverse primer <400> 28 aaagaattca tggagcgaag aaacccatct gagcggggag tacctgctgg attctctggc 60 catgcatctg tggagagcgg ttgtgagaca caagaatcgc ctgctactgt tgtcttccgt 120 ccgcccggcg ataataccga cggaggagca gcagcagcag caggaggaag ccaggcggcg 180 gcggcaggag cagagcccat ggaacccgag agccggcctg gaccctcggg aatgaatgtt 240 gtacaggtgg ctgaactgta tccagaactg agacgcattt tgacaattac agaggatggg 300 caggggctaa agggggtaaa gagggagcgg ggggcttgtg aggctacaga ggaggctagg 360 aatctagctt ttagcttaat gaccagacac cgtcctgagt gtattacttt tcaacagatc 420 aaggataatt gcgctaatga gctgatctgc gcgcagacgc gccaacaaaa caagagtcca 480 gtc 483 <210> 29 <211> 1246 <212> DNA <213> Artificial Sequence <220> <223> primer:E1B55K In-fusion BamHI antisense <400> 29 aaaggatggc agggctaaag gggtaaagag gagcgggggc ttggaggcta cagaggaggc 60 taggaatcta gcttttagct taatgaccag acaccgtcct gagtgtatta cttttcaaca 120 gatcaaggat aattgcgcta atgagcttga tctgctggcg cagaagtatt ccatagagca 180 gctgaccact tactggctgc agccagggga tgattttgag gaggctatta gggtatatgc 240 aaaggtggca cttaggccag attgcaagta caagatcagc aaacttgtaa atatcaggaa 300 ttgttgctac atctctggga acggggccga ggtggagata gatacggagg atagggtggc 360 ctttagatgt agctctggga acggggccga ggtggagata gatacggagg atagggtggc 420 ctttagatgt agctctggga acggggccga ggtggagata gatacggagg atagggtggc 480 ctttagatgt agctttactg gccccaattt tagcggtacg gttttcctgg ccaataccaa 540 ccttatccta cacggtgtta gcttctatgg gtttaacaat acctgtgtgg aagcctggac 600 cgatgtaagg gttcggggct gtgcctttta ctgctgctgg aagggggtgg tgtgtcgccc 660 caaaagcagg gcttcaatta agaaatgcct ctttgaaagg tgtaccttgg gtatcctgtc 720 tgagggtaac tccagggtgc gccacaatgt ggcctccgac tgtggttgct tcatgctagt 780 gaaaagcgtg gctgtgatta agcataacat ggtatgtggc aactgcgagg acagggcctc 840 tcagatgctg acctgctcgg acggcaactg tcacctgctg aagaccattc acgtagccag 900 ccactctcgc aaggcctggc cagtgtttga gcataacata ctgacccgct gttccttgca 960 tttgggtaac aggagggggg tgttcctacc ttaccaatgc aatttgagtc acactaagat 1020 attgcttgag cccgagagca tgtccaaggt gaacctgaac ggggtgtttg acatgaccat 1080 gaagatctgg aaggtgctga ggtacgatga gacccgcacc aggtgcagac cctgcgagtg 1140 tggcggtaaa catattagga accagcctgt gatgctggat gtgaccgagg agctgaggcc 1200 cgatcacttg gtgctggcct gcacccgcgc tgagtttggc ccccgt 1246 <210> 30 <211> 995 <212> DNA <213> Artificial Sequence <220> <223> pcDNA3.1 GRP78 forward <400> 30 tggtggaatt ctgcagatat ccagcacagt ggcggccgct cgagatgaag ctctccctgg 60 tggccgcgat gctgctgctg ctcagcgcgg cgcgggccga ggaggaggac aagaaggagg 120 acgtgggcac ggtggtcggc atcgacctgg ggaccaccta ctcctgcgtc ggcgtgttca 180 agaacggccg cgtggagatc atcgccaacg atcagggcaa ccgcatcacg ccgtcctatg 240 tcgccttcac tcctgaaggg gaacgtctga ttggcgatgc cgccaagaac cagctcacct 300 ccaaccccga gaacacggtc tttgacgcca agcggctcat cggccgcacg tggaatgacc 360 cgtctgtgca gcaggacatc aagttcttgc cgttcaaggt ggttgaaaag aaaactaaac 420 catacattca agttgatatt ggaggtgggc aaacaaagac atttgctcct gaagaaattt 480 ctgccatggt tctcactaaa atgaaagaaa ccgctgaggc ttatttggga aagaaggtta 540 cccatgcagt tgttactgta ccagcctatt ttaatgatgc ccaacgccaa gcaaccaaag 600 acgctggaac tattgctggc ctaaatgtta tgaggatcat caacgagcct acggcagctg 660 ctattgctta tggcctggat aagagggagg gggagaagaa catcctggtg tttgacctgg 720 gtggcggaac cttcgatgtg tctcttctca ccattgacaa tggtgtcttc gaagttgtgg 780 ccactaatgg agatactcat ctgggtggag aagactttga ccagcgtgtc atggaacact 840 tcatcaaact gtacaaaaag aagacgggca aagatgtcag gaaagacaat agagctgtgc 900 agaaactccg gcgcgaggta gaaaaggcca aacgggccct gtcttctcag catcaagcaa 960 gaattgaaat tgagtccttc tatgaaggag aagac 995 <210> 31 <211> 1046 <212> DNA <213> Artificial Sequence <220> <223> pcDNA3.1 GRP78 reverse <400> 31 tctatgaagg agaagacttt tctgagaccc tgactcgggc caaatttgaa gagctcaaca 60 tggatctgtt ccggtctact atgaagcccg tccagaaagt gttggaagat tctgatttga 120 agaagtctga tattgatgaa attgttcttg ttggtggctc gactcgaatt ccaaagattc 180 agcaactggt taaagagttc ttcaatggca aggaaccatc ccgtggcata aacccagatg 240 aagctgtagc gtatggtgct gctgtccagg ctggtgtgct ctctggtgat caagatacag 300 gtgacctggt actgcttgat gtatgtcccc ttacacttgg tattgaaact gtgggaggtg 360 tcatgaccaa actgattcca aggaacacag tggtgcctac caagaagtct cagatctttt 420 ctacagcttc tgataatcaa ccaactgtta caatcaaggt ctatgaaggt gaaagacccc 480 tgacaaaaga caatcatctt ctgggtacat ttgatctgac tggaattcct cctgctcctc 540 gtggggtccc acagattgaa gtcacctttg agatagatgt gaatggtatt cttcgagtga 600 cagctgaaga caagggtaca gggaacaaaa ataagatcac aatcaccaat gaccagaatc 660 gcctgacacc tgaagaaatc gaaaggatgg ttaatgatgc tgagaagttt gctgaggaag 720 acaaaaagct caaggagcgc attgatacta gaaatgagtt ggaaagctat gcctattctc 780 taaagaatca gattggagat aaagaaaagc tgggaggtaa actttcctct gaagataagg 840 agaccatgga aaaagctgta gaagaaaaga ttgaatggct ggaaagccac caagatgctg 900 acattgaaga cttcaaagct aagaagaagg aactggaaga aattgttcaa ccaattatca 960 gcaaactcta tggaagtgca ggccctcccc caactggtga agaggataca gcagaaaaag 1020 atgagttgta gtctagagtc ccgtaa 1046 <110> Industry-Academic Cooperation Foundation, Yonsei University <120> Mesenchymal stem cells capable of improving tumor targeting and mass production of viruses <130> P21U18C1147 <150> KR 10-2020-0139918 <151> 2020-10-27 <160 > 31 <170> KoPatentIn 3.0 <210> 1 <211> 1965 <212> DNA <213> Homo sapiens <400> 1 atgaagctct ccctggtggc cgcgatgctg ctgctgctca gcgcggcgcg ggccgaggag 60 gaggacaaga aggaggacgt gggcacggtg gtcggcatcg acctggggac cacctactcc 120 tgcgtcggcg tgttcaagaa cggccgcgtg gagatcatcg ccaacgatca gggcaaccgc 180 atcacgccgt cctatgtcgc cttcactcct gaaggggaac gtctgattgg cgatgccgcc 240 aagaaccagc tcacctccaa ccccgagaac acggtctttg acgccaagcg gctcatcggc 300 cgcacgtgga atgacccgtc tgtgcagcag gacatcaagt tcttgccgtt caaggtggtt 360 gaaaagaaaa ctaaaccata cattcaagtt gatattggag gtgggcaaac aaagacattt 420 gctcctgaag aaatttctgc catggttctc actaaaatga aagaaaccgc tgaggcttat 480 ttgggaaaga aggttaccca tgcagttgtt actgtaccag cctattttaa tgatgcccaa 540 cgccaagcaa ccaaagacgc tggaactatt gctggcctaa atgttatgag gatcatc aac 600 gagcctacgg cagctgctat tgcttatggc ctggataaga gggaggggga gaagaacatc 660 ctggtgtttg acctgggtgg cggaaccttc gatgtgtctc ttctcaccat tgacaatggt 720 gtcttcgaag ttgtggccac taatggagat actcatctgg gtggagaaga ctttgaccag 780 cgtgtcatgg aacacttcat caaactgtac aaaaagaaga cgggcaaaga tgtcaggaaa 840 gacaatagag ctgtgcagaa actccggcgc gaggtagaaa aggccaaacg ggccctgtct 900 tctcagcatc aagcaagaat tgaaattgag tccttctatg aaggagaaga cttttctgag 960 accctgactc gggccaaatt tgaagagctc aacatggatc tgttccggtc tactatgaag 1020 cccgtccaga aagtgttgga agattctgat ttgaagaagt ctgatattga tgaaattgtt 1080 cttgttggtg gctcgactcg aattccaaag attcagcaac tggttaaaga gttcttcaat 1140 ggcaaggaac catcccgtgg cataaaccca gatgaagctg tagcgtatgg tgctgctgtc 1200 caggctggtg tgctctctgg tgatcaagat acaggtgacc tggtactgct tgatgtatgt 1260 ccccttacac ttggtattga aactgtggga ggtgtcatga ccaaactgat tccaaggaac 1320 acagtggtgc ctaccaagaa gtctcagatc ttttctacag cttctgataa tcaaccaact 1380 gttacaatca aggtctatga aggtgaaaga cccctgacaa aagacaatca tcttctgggt 1440 acat ttgatc tgactggaat tcctcctgct cctcgtgggg tcccacagat tgaagtcacc 1500 tttgagatag atgtgaatgg tattcttcga gtgacagctg aagacaaggg tacagggaac 1560 aaaaataaga tcacaatcac caatgaccag aatcgcctga cacctgaaga aatcgaaagg 1620 atggttaatg atgctgagaa gtttgctgag gaagacaaaa agctcaagga gcgcattgat 1680 actagaaatg agttggaaag ctatgcctat tctctaaaga atcagattgg agataaagaa 1740 aagctgggag gtaaactttc ctctgaagat aaggagacca tggaaaaagc tgtagaagaa 1800 aagattgaat ggctggaaag ccaccaagat gctgacattg aagacttcaa agctaagaag 1860 aaggaactgg aagaaattgt tcaaccaatt atcagcaaac tctatggaag tgcaggccct 1920 cccccaactg gtgaagagga tacagcagaa aaagatgagt tgtag 1965 <210> 2 <211> 3399 <212> DNA <213> Homo sapiens <400> 2 atgccgcgcg ctccccgctg ccgagccgtg cgctccctgc tgcgcagcca ctaccgcgag 60 gtgctgccgc tggccacgtt cgtgcggcgc ctggggcccc agggctggcg gctggtgcag 120 cgcggggacc cggcggcttt ccgcgcgctg gtggcccagt gcctggtgtg cgtgccctgg 180 gacgcacggc cgccccccgc cgccccctcc ttccgccagg tgtcctgcct gaaggagctg 240 gtggcccgag tgctgcagag gctgtgcgag cgcggcgcga ag aacgtgct ggccttcggc 300 ttcgcgctgc tggacggggc ccgcgggggc ccccccgagg ccttcaccac cagcgtgcgc 360 agctacctgc ccaacacggt gaccgacgca ctgcggggga gcggggcgtg ggggctgctg 420 ctgcgccgcg tgggcgacga cgtgctggtt cacctgctgg cacgctgcgc gctctttgtg 480 ctggtggctc ccagctgcgc ctaccaggtg tgcgggccgc cgctgtacca gctcggcgct 540 gccactcagg cccggccccc gccacacgct agtggacccc gaaggcgtct gggatgcgaa 600 cgggcctgga accatagcgt cagggaggcc ggggtccccc tgggcctgcc agccccgggt 660 gcgaggaggc gcgggggcag tgccagccga agtctgccgt tgcccaagag gcccaggcgt 720 ggcgctgccc ctgagccgga gcggacgccc gttgggcagg ggtcctgggc ccacccgggc 780 aggacgcgtg gaccgagtga ccgtggtttc tgtgtggtgt cacctgccag acccgccgaa 840 gaagccacct ctttggaggg tgcgctctct ggcacgcgcc actcccaccc atccgtgggc 900 cgccagcacc acgcgggccc cccatccaca tcgcggccac cacgtccctg ggacacgcct 960 tgtcccccgg tgtacgccga gaccaagcac ttcctctact cctcaggcga caaggagcag 1020 ctgcggccct ccttcctact cagctctctg aggcccagcc tgactggcgc tcggaggctc 1080 gtggagacca tctttctggg ttccaggccc tggatgccag ggactccccg caggttgcc c 1140 cgcctgcccc agcgctactg gcaaatgcgg cccctgtttc tggagctgct tgggaaccac 1200 gcgcagtgcc cctacggggt gctcctcaag acgcactgcc cgctgcgagc tgcggtcacc 1260 ccagcagccg gtgtctgtgc ccgggagaag ccccagggct ctgtggcggc ccccgaggag 1320 gaggacacag acccccgtcg cctggtgcag ctgctccgcc agcacagcag cccctggcag 1380 gtgtacggct tcgtgcgggc ctgcctgcgc cggctggtgc ccccaggcct ctggggctcc 1440 aggcacaacg aacgccgctt cctcaggaac accaagaagt tcatctccct ggggaagcat 1500 gccaagctct cgctgcagga gctgacgtgg aagatgagcg tgcgggactg cgcttggctg 1560 cgcaggagcc caggggttgg ctgtgttccg gccgcagagc accgtctgcg tgaggagatc 1620 ctggccaagt tcctgcactg gctgatgagt gtgtacgtcg tcgagctgct caggtctttc 1680 ttttatgtca cggagaccac gtttcaaaag aacaggctct ttttctaccg gaagagtgtc 1740 tggagcaagt tgcaaagcat tggaatcaga cagcacttga agagggtgca gctgcgggag 1800 ctgtcggaag cagaggtcag gcagcatcgg gaagccaggc ccgccctgct gacgtccaga 1860 ctccgcttca tccccaagcc tgacgggctg cggccgattg tgaacatgga ctacgtcgtg 1920 ggagccagaa cgttccgcag agaaaagagg gccgagcgtc tcacctcgag ggtgaaggca 1980 ctgttcagcg tgctcaacta cgagcgggcg cggcgccccg gcctcctggg cgcctctgtg 2040 ctgggcctgg acgatatcca cagggcctgg cgcaccttcg tgctgcgtgt gcgggcccag 2100 gacccgccgc ctgagctgta ctttgtcaag gtggatgtga cgggcgcgta cgacaccatc 2160 ccccaggaca ggctcacgga ggtcatcgcc agcatcatca aaccccagaa cacgtactgc 2220 gtgcgtcggt atgccgtggt ccagaaggcc gcccatgggc acgtccgcaa ggccttcaag 2280 agccacgtct ctaccttgac agacctccag ccgtacatgc gacagttcgt ggctcacctg 2340 caggagacca gcccgctgag ggatgccgtc gtcatcgagc agagctcctc cctgaatgag 2400 gccagcagtg gcctcttcga cgtcttccta cgcttcatgt gccaccacgc cgtgcgcatc 2460 aggggcaagt cctacgtcca gtgccagggg atcccgcagg gctccatcct ctccacgctg 2520 ctctgcagcc tgtgctacgg cgacatggag aacaagctgt ttgcggggat tcggcgggac 2580 gggctgctcc tgcgtttggt ggatgatttc ttgttggtga cacctcacct cacccacgcg 2640 aaaaccttcc tcaggaccct ggtccgaggt gtccctgagt atggctgcgt ggtgaacttg 2700 cggaagacag tggtgaactt ccctgtagaa gacgaggccc tgggtggcac ggcttttgtt 2760 cagatgccgg cccacggcct attcccctgg tgcggcctgc tgctggatac ccggaccctg 2820 gaggt gcaga gcgactactc cagctatgcc cggacctcca tcagagccag tctcaccttc 2880 aaccgcggct tcaaggctgg gaggaacatg cgtcgcaaac tctttggggt cttgcggctg 2940 aagtgtcaca gcctgtttct ggatttgcag gtgaacagcc tccagacggt gtgcaccaac 3000 atctacaaga tcctcctgct gcaggcgtac aggtttcacg catgtgtgct gcagctccca 3060 tttcatcagc aagtttggaa gaaccccaca tttttcctgc gcgtcatctc tgacacggcc 3120 tccctctgct actccatcct gaaagccaag aacgcaggga tgtcgctggg ggccaagggc 3180 gccgccggcc ctctgccctc cgaggccgtg cagtggctgt gccaccaagc attcctgctc 3240 aagctgactc gacaccgtgt cacctacgtg ccactcctgg ggtcactcag gacagcccag 3300 acgcagctga gtcggaagct cccggggacg acgctgactg ccctggaggc cgcagccaac 3360 ccggcactgc cctcagactt caagaccatc ctggactga 3399 <210> 3 <211> 1491 <212> DNA <213> Human adenovirus type 5 <400> 3 atggagcgaa gaaacccatc tgagcgggga gtacctgctg gattttctgg ccatgcatct 60 gtggagagcg gttgtgagac acaagaatcg cctgctactg ttgtcttccg tccgcccggc 120 gataataccg acggaggagc agcagcagca gcaggaggaa gccaggcggc ggcggcagga 180 gcagagccca tggaacccga gagccggcct ggaccctcg g gaatgaatgt tgtacaggtg 240 gctgaactgt atccagaact gagacgcatt ttgacaatta cagaggatgg gcaggggcta 300 aagggggtaa agagggagcg gggggcttgt gaggctacag aggaggctag gaatctagct 360 tttagcttaa tgaccagaca ccgtcctgag tgtattactt ttcaacagat caaggataat 420 tgcgctaatg agcttgatct gctggcgcag aagtattcca tagagcagct gaccacttac 480 tggctgcagc caggggatga ttttgaggag gctattaggg tatatgcaaa ggtggcactt 540 aggccagatt gcaagtacaa gatcagcaaa cttgtaaata tcaggaattg ttgctacatt 600 tctgggaacg gggccgaggt ggagatagat acggaggata gggtggcctt tagatgtagc 660 atgataaata tgtggccggg ggtgcttggc atggacgggg tggttattat gaatgtaagg 720 tttactggcc ccaattttag cggtacggtt ttcctggcca ataccaacct tatcctacac 780 ggtgttagct tctatgggtt taacaatacc tgtgtggaag cctggaccga tgtaagggtt 840 cggggctgtg ccttttactg ctgctggaag ggggtggtgt gtcgccccaa aagcagggct 900 tcaattaaga aatgcctctt tgaaaggtgt accttgggta tcctgtctga gggtaactcc 960 agggtgcgcc acaatgtggc ctccgactgt ggttgcttca tgctagtgaa aagcgtggct 1020 gtgattaagc ataacatggt atgtggcaac tgcgaggaca gggcctctca gatgct gacc 1080 tgctcggacg gcaactgtca cctgctgaag accattcacg tagccagcca ctctcgcaag 1140 gcctggccag tgtttgagca taacatactg acccgctgtt ccttgcattt gggtaacagg 1200 aggggggtgt tcctacctta ccaatgcaat ttgagtcaca ctaagatatt gcttgagccc 1260 gagagcatgt ccaaggtgaa cctgaacggg gtgtttgaca tgaccatgaa gatctggaag 1320 gtgctgaggt acgatgagac ccgcaccagg tgcagaccct gcgagtgtgg cggtaaacat 1380 attaggaacc agcctgtgat gctggatgtg accgaggagc tgaggcccga tcacttggtg 1440 ctggcctgca cccgcgctga gtttggctct agcgatgaag atacagattg a 1491 <210> 4 <211> 29 <212> DNA <213> Artificial Sequence <220> <223> BamHI/NotI forward primer <400> 4 gcggatccat ggagcgaaga aacccatct 29 <210> 5 <211> 28 <212> DNA < 213> Artificial Sequence <220> <223> BamHI/NotI reverse primer <400> 5 cggccgctca atctgtatct tcatcgct 28 <210> 6 <211> 30 <212> DNA <213> Artificial Sequence <220> <223> HindIII forward primer < 400> 6 gtacaagctt atgactacgt ccggcgttcc 30 <210> 7 <211> 30 <212> DNA <213> Artificial Sequence <220> <223> XbaI reverse primer <400> 7 cacctctaga ctacatgggg gtagagtcat 30 <210> 8 <211> 30 <212> DNA <213> Artificial Sequence <220> <223> CMV30 <400> 8 aatgtcgtaa taaccccgcc ccgttgacgc 30 <210> 9 <211> 30 <212> DNA <213> Artificial Sequence <220> <223> XbaI sense primer <400> 9 ttcatctaga atggagcgaa gaaacccatc 30 <210> 10 <211> 30 <212> DNA <213> Artificial Sequence <220> <223> HindIII antisense primer <400> 10 gacgaagctt tcaatctgta tcttcatcgc 30 <210> 11 <211> 25 <212> DNA <213> Artificial Sequence <220> <223> hCMV forward primer <400> 11 gggaggtcta tataagcaga gctcg 25 <210> 12 <211> 25 <212> DNA < 213> Artificial Sequence <220> <223> pCA14 SV40 reverse primer <400> 12 catgatcgat gctagacgat ccaga 25 <210> 13 <211> 25 <212> PRT <213> Artificial Sequence <220> <223> N terminus of E1B55K < 400> 13 Met Glu Arg Arg Asn Pro Ser Glu Arg Gly Val Pro Ala Gly Phe Ser 1 5 10 15 Gly His Ala Ser Val Glu Ser Gly Cys 20 25 <210> 14 <211> 40 <212> DNA <213> Artificial Sequence <220> <223> E1B55K In-fusion EcoRI sense primer <400> 14 c cctcgtaaa gaattcatgg agcgaagaaa cccatctgag 40 <210> 15 <211> 40 <212> DNA <213> Artificial Sequence <220> <223> E1B55K In-fusion BamHI antisense primer <400> 15 gaggtggtct ggatcctcaa tctgtatctt < catcgctaga 40 > 26 <212> DNA <213> Artificial Sequence <220> <223> XbaI Forward primer <400> 16 gattctcgag atgaagctct ccctgg 26 <210> 17 <211> 26 <212> DNA <213> Artificial Sequence <220> <223 > XbaI Reverse primer <400> 17 ggcctctaga ctacaactca tctttt 26 <210> 18 <211> 62 <212> DNA <213> Artificial Sequence <220> <223> pLNCX neo Top strand <400> 18 agcttcacgt gccagcaacag tggcggccgc tcgagtcgac gggccc 60 at 62 <210> 19 <211> 60 <212> DNA <213> Artificial Sequence <220> <223> pLNCX neo Bottom strand <400> 19 cgatgttaac gtttaaacgg gcccgtcgac tcgagcggcc gccactgtgc tggcacgtga 60 60 <210> 20 <211> 20 < 212> DNA <213> Artificial Sequence <220> <223> E4 ORF Forward primer <400> 20 cgtggtcaaa ctctacagcc 20 <210> 21 <211> 20 <212> DNA <213> Artificial Sequence <220> <223> E4 ORF R everse primer <400> 21 gcatgagcat gactacgatg 20 <210> 22 <211> 912 <212> DNA <213> Artificial Sequence <220> <223> Flag-E4orf6 <400> 22 gactacaaag acgatgacga caagcttatg actacgtccg gcgttccatt tggcatgacaca 60 ctacgaccc acagtaggga tcgtctacct 120 ccttttgaga cagaaacccg cgctaccata ctggaggatc atccgctgct gcccgaatgt 180 aacactttga caatgcacaa cgtgagttac gtgcgaggtc ttccctgcag tgtgggattt 240 acgctgattc aggaatgggt tgttccctgg gatatggttc taacgcggga ggagcttgta 300 atcctgagga agtgtatgca cgtgtgcctg tgttgtgcca acattgatat catgacgagc 360 atgatgatcc atggttacga gtcctgggct ctccactgtc attgttccag tcccggttcc 420 ctgcagtgta tagccggcgg gcaggttttg gccagctggt ttaggatggt ggtggatggc 480 gccatgttta atcagaggtt tatatggtac cgggaggtgg tgaattacaa catgccaaaa 540 gaggtaatgt ttatgtccag cgtgtttatg aggggtcgcc acttaatcta cctgcgcttg 600 tggtatgatg gccacgtggg ttctgtggtc cccgccatga gctttggata cagcgccttg 660 cactgtggga ttttgaacaa tattgtggtg ctgtgctgca gttactgtgc tgatttaagt 720 gagatcaggg tgcgctgctg tgc ccggagg acaaggcgcc ttatgctgcg ggcggtgcga 780 atcatcgctg aggagaccac tgccatgttg tattcctgca ggacggagcg gcggcggcag 840 cagtttattc gcgcgctgct gcagcaccac cgccctatcc tgatgcacga ttatgactct 900 acccccatgt ag 912 <210> 23 <211> 1196 <212> DNA <213> Artificial Sequence <220> <223> sample 2-Fig. 7 <400> 23 aaccgtcaga attgatctac catggactac aaagacgatg acgacaagct tatgactacg 60 tccggcgttc catttggcat gacactacga ccaacacgat ctcggttgtc tcggcgcact 120 ccgtacagta gggatcgtct acctcctttt gagacagaaa cccgcgctac catactggag 180 gatcatccgc tgctgcccga atgtaacact ttgacaatgc acaacgtgag ttacgtgcga 240 ggtcttccct gcagtgtggg atttacgctg attcaggaat gggttgttcc ctgggatatg 300 gttctaacgc gggaggagct tgtaatcctg aggaagtgta tgcacgtgtg cctgtgttgt 360 gccaacattg atatcatgac gagcatgatg atccatggtt acgagtcctg ggctctccac 420 tgtcattgtt ccagtcccgg ttccctgcag tgtatagccg gcgggcaggt tttggccagc 480 tggtttagga tggtggtgga tggcgccatg tttaatcaga ggtttatatg gtaccgggag 540 gtggtgaatt acaacatgcc aaaagaggta atgtttatgt ccagcgtgtt tatgaggggt 600 cgccacttaa tctacctgcg cttgtggtat gatggccacg tgggttctgt ggtccccgcc 660 atgagctttg gatacagcgc cttgcactgt gggattttga acaatattgt ggtgctgtgc 720 tgcagttact gtgctgattt aagtgagatc agggtgcgct gctgtgcccg gaggacaagg 780 cgccttatgc tgcgggcggt gcgaatcatc gctgaggaga ccactgccat gttgtattcc 840 tgcaggacgg agcggcggcg gcagcagttt attcgcgcgc tgctgcagca ccaccgccct 900 atcctgatgc acgattatga ctctaccccc atgtagtcta gaggatcccg ggtggcatcc 960 ctgtgacccc tccccagtgc ctctcctggc cctggaagtt gccactccag tgcccaccag 1020 ccttgtccta ataaaattaa gttgcatcat tttgtctgac taggtgtcct tctataatat 1080 tatggggtgg aggggggggg tatggaacca aggggcaagt tgggaaaaaa acctgaaggg 1140 cctgcgggtc ttattgggaa ccaaactggg agtgcagtgg accaattttg ggttcc 1196 <210> 24 <211> 960 < 212> DNA <213> Artificial Sequence <220> <223> pCA14-E1B55K forward <400> 24 aagacaccgg gaccgatcca gcctggggat cttcgagtcg agggatccct cgagtctaga 60 atggagcgaa gaaacccatc tgagcgggga gtacctgctg gattttctgg ccatgcatct 120 gtggagagcg gttgtgagac acaagaatcg cctgctactg ttgtcttccg tccgcccggc 180 gataataccg acggaggagc agcagcagca gcaggaggaa gccaggcggc ggcggcagga 240 gcagagccca tggaacccga gagccggcct ggaccctcgg gaatgaatgt tgtacaggtg 300 gctgaactgt atccagaact gagacgcatt ttgacaatta cagaggatgg gcaggggcta 360 aagggggtaa agagggagcg gggctagcttgt gaggctag gcttaa tgaccagaca ccgtcctgag tgtattactt ttcaacagat caaggataat 480 tgcgctaatg agcttgatct gctggcgcag aagtattcca tagagcagct gaccacttac 540 tggctgcagc caggggatga ttttgaggag gctattaggg tatatgcaaa ggtggcactt 600 aggccagatt gcaagtacaa gatcagcaaa cttgtaaata tcaggaattg ttgctacatt 660 tctgggaacg gggccgaggt ggagatagat acggaggata gggtggcctt tagatgtagc 720 atgataaata tgtggccggg ggtgcttggc atggacgggg tggttattat gaatgtaagg 780 tttactggcc ccaattttag cggtacggtt ttcctggcca ataccaacct tatcctacac 840 ggtgttagct tctatgggtt taacaatacc tgtgtggaag cctggaccga tgtaagggtt 900 cggggctgtg ccttttactg ctgctggaag ggggtggtgt gtcgccccaa aagcagggct 960 960 <210> 25 <211> 1017 <212> DNA <213> Artificial Sequence <220> <223> pCA14-E1B55K-reverse <400> 25 tttggtccaa ccggggatga tttgaggggg cttttgggtt tttgcaaagg tgcccttagg 60 ccagattgca attacaaaat cagcaaactt gtaaatttca ggaattgttg ctacatttct 120 gggaacgggg ccgaggtgga gatagatacg gaggataggg tggcctttag atgtagcatgt ttagg g ataggaggt tgg ttagg ttaggagggt gg tttgcaaagg tt 240 actggcccca attttagcgg tacggttttc ctggccaata ccaaccttat cctacacggt 300 gttagcttct atgggtttaa caatacctgt gtggaagcct ggaccgatgt aagggttcgg 360 ggctgtgcct tttactgctg ctggaagggg gtggtgtgtc gccccaaaag cagggcttca 420 attaagaaat gcctctttga aaggtgtacc ttgggtatcc tgtctgaggg taactccagg 480 gtgcgccaca atgtggcctc cgactgtggt tgcttcatgc tagtgaaaag cgtggctgtg 540 attaagcata acatggtatg tggcaactgc gaggacaggg cctctcagat gctgacctgc 600 tcggacggca actgtcacct gctgaagacc attcacgtag ccagccactc tcgcaaggcc 660 tggccagtgt ttgagcataa catactgacc cgctgttcct tgcatttggg taacaggagg 720 ggggtgttcc taccttacca atgcaatttg agtcacacta agatattgct tgagcccgag 780 agcatgtcca aggtgaacct gaacggggtg tttgacatga ccatgaagat ctggaaggtg 840 ctgaggtacg atgagacccg caccaggtgc agaccctgcg agtgtggcgg taaacatatt 900 aggaaccagc ctgtgatgct ggatgtgacc gaggagctga ggcccgatca cttggtgctg 960 gcctgcaccc gcgctgagtt tggctctagc gatgaagata cagattgaaa gcttgtc 1017 <210> 26 <211> 1172 <212> DNA <213> Artificial Sequence <220> <223> primer E1B55K In-fusion EcoRI sense <400> 26 ccggggggca gtacctgctg gattctctgg ccatgcatct gtggagagcg gttgtgagac 60 acaagaatcg cctgctactg ttgtcttccg tccgcccggc gataataccg acggaggagc 120 agcagcagca gcaggaggaa gccaggcggc ggcggcagga gcagagccca tggaacccga 180 gagccggcct ggaccctcgg gaatgaatgt tgtacaggtg gctgaactgt atccagaact 240 gagacgcatt ttgacaatta cagaggatgg gcaggggcta aagggggtaa agagggagcg 300 gggggcttgt gaggctacag aggaggctag gaatctagct tttagcttaa tgaccagaca 360 ccgtcctgag tgtattactt ttcaacagat caaggataat tgcgctaatg agcttgatct 420 gctggcgcag aagtattcca tagagcagct gaccacttac tggctgcagc caggggatga 480 ttttgaggag gctattaggg tatatgcaaa ggtggcactt aggccagatt gcaagtacaa 540 gatcagcaaa cttgtaaata tcaggaattg ttgctacatc tctgggaacg gggccgaggt 600 ggagatagat acggaggata gggtggcctt tagatgtagc atgataaata tgtggccggg 660 ggtgcttggc atggacgggg tggttattat gaatgtaagg tttactggcc ccaattttag 720 cggtacggtt ttcctggcca ataccaacct tatcctacac ggtgttagct tctatgggtt 780 taacaatacc tgtgtggaag cctggaccga t gtaagggtt cggggctgtg ccttttactg 840 ctgctggaag ggggtggtgt gtcgccccaa aagcagggct tcaattaaga aatgcctctt 900 tgaaaggtgt accttgggta tcctgtctga gggtaactcc agggtgcgcc acaatgtggc 960 ctccgactgt ggttgcttca tgctagtgaa aagcgtggct gtgattaagc ataacatggt 1020 atgtggcaac tgcgaggaca gggcctctca gatgctgacc tgctcggacg gcaactgtca 1080 cctgctgaag acattcacgt agccagccct ttcgcaaggc tggccagggt tgagcatacc 1140 tactgacccc ctgttccttg ctttgggaaa aa 1172 <210> 27 <211 > 686 <212> DNA <213> Artificial Sequence <220> <223> primer: E1B55K internal primer <400> 27 acctgtaatt tgtttatttg ggcgtaggtc gggcgtgctt ttactgctgc tggaaggggg 60 tggtgtgtcg ccccaaaagc agggcttcaa ttaagaaatg cctctttgaa aggtgtacct 120 tgggtatcct gtctgagggt aactccaggg tgcgccacaa tgtggcctcc gactgtggtt 180 gcttcatgct agtgaaaagc gtggctgtga ttaagcataa catggtatgt ggcaactgcg 240 aggacagggc ctctcagatg ctgacctgct cggacggcaa ctgtcacctg ctgaagacca 300 ttcacgtagc cagccactct cgcaaggcct ggccagtgtt acatagtgagcata gggtgttggcct accttaccaa tgcaatttga 420 gtcacactaa gatattgctt gagcccgaga gcatgtccaa ggtgaacctg aacggggtgt 480 ttgacatgac catgaagatc tggaaggtgc tgaggtacga tgagacccgc accaggtgca 540 gaccctgcga gtgtggcggt aaacatatta ggaaccagcc tgtgatgctg gatgtgaccg 600 aggagctgag gcccgatcac ttggtgctgg cctgcacccg cgctgagttt ggctctagcg 660 atgaagatac agattgagga tccaga 686 <210> 28 <211> 483 <212> DNA <213> Artificial Sequence <220> <223> E1B55K 5' near internal reverse primer <400> 28 aaagaattca tggagcgaag aaacccatct gagcggggag tacctgctgg attctctggc 60 catgcatctg tggagagcgg ttgtgagaca caagaatcgc ctgctactgt tgtcttccgt 120 ccgcccggcg ataataccga cggaggagca gcagcagcag caggaggaag ccaggcggcg 180 gcggcaggag cagagcccat ggaacccgag agccggcctg gaccctcggg aatgaatgtt 240 gtacaggtgg ctgaactgta tccagaactg agacgcattt tgacaattac agaggatggg 300 caggggctaa agggggtaaa gagggagcgg ggggcttgtg aggctacaga ggaggctagg 360 aatctagctt ttagcttaat gaccagacacc cgtcctgagt gtattacttc caggtgagt gtattacttg ca gacaggatg ac taat agagtcca 480 gtc 483 <210> 29 <211> 1246 <212> DNA <213> Artificial Sequence <220> <223> primer:E1B55K In-fusion BamHI antisense <400> 29 aaaggatggc agggctaaag gggtaaagag gagctttggggc ttggaggc 60 taggggc ttggaggc accta cagatgaccag gagtgtatta cttttcaaca 120 gatcaaggat aattgcgcta atgagcttga tctgctggcg cagaagtatt ccatagagca 180 gctgaccact tactggctgc agccagggga tgattttgag gaggctatta gggtatatgc 240 aaaggtggca cttaggccag attgcaagta caagatcagc aaacttgtaa atatcaggaa 300 ttgttgctac atctctggga acggggccga ggtggagata gatacggagg atagggtggc 360 ctttagatgt agctctggga acggggccga ggtggagata gatacggagg atagggtggc 420 ctttagatgt agctctggga acggggccga ggtggagata gatacggagg atagggtggc 480 ctttagatgt agctttactg gccccaattt tagcggtacg gttttcctgg ccaataccaa 540 ccttatccta cacggtgtta gcttctatgg gtttaacaat acctgtgtgg aagcctggac 600 cgatgtaagg gttcggggct gtgcctttta ctgctgctgg aagggtgg tggtgtcgcct tggat ggt tggtcgcct tggat ggt tggtcgccc 660 gt caaattacctgt g ccacaatgt ggcctccgac tgtggttgct tcatgctagt 780 gaaaagcgtg gctgtgatta agcataacat ggtatgtggc aactgcgagg acagggcctc 840 tcagatgctg acctgctcgg acggcaactg tcacctgctg aagaccattc acgtagccag 900 ccactctcgc aaggcctggc cagtgtttga gcataacata ctgacccgct gttccttgca 960 tttgggtaac aggagggggg tgttcctacc ttaccaatgc aatttgagtc acactaagat 1020 attgcttgag cccgagagca tgtccaaggt gaacctgaac ggggtgtttg acatgaccat 1080 gaagatctgg aaggtgctga ggtacgatga gacccgcacc aggtgcagac cctgcgagtg 1140 tggcggtaaa catattagga accagcctgt gatgctggat gtgaccgagg agctgaggcc 1200 cgatcacttg gtgctggcct gcacccgcgc tgagtttggc ccccgt 1246 <210> 30 <211> 995 <212> DNA <213> Artificial Sequence <220> <223> pcgctDNA3.1 GRP78 forward cggcctcgt cgg cgg t ccgcctgt cgg cggt gctgctgctg ctcagcgcgg cgcgggccga ggaggaggac aagaaggagg 120 acgtgggcac ggtggtcggc atcgacctgg ggaccaccta ctcctgcgtc ggcgtgttca 180 agaacggacccg cgtggagtatc atcg tcca cc tga cgtctga ttggcgatgc cgccaagaac cagctcacct 300 ccaaccccga gaacacggtc tttgacgcca agcggctcat cggccgcacg tggaatgacc 360 cgtctgtgca gcaggacatc aagttcttgc cgttcaaggt ggttgaaaag aaaactaaac 420 catacattca agttgatatt ggaggtgggc aaacaaagac atttgctcct gaagaaattt 480 ctgccatggt tctcactaaa atgaaagaaa ccgctgaggc ttatttggga aagaaggtta 540 cccatgcagt tgttactgta ccagcctatt ttaatgatgc ccaacgccaa gcaaccaaag 600 acgctggaac tattgctggc ctaaatgtta tgaggatcat caacgagcct acggcagctg 660 ctattgctta tggcctggat aagagggagg gggagaagaa catcctggtg tttgacctgg 720 gtggcggaac cttcgatgtg tctcttctca ccattgacaa tggtgtcttc gaagttgtgg 780 ccactaatgg agatactcat ctgggtggag aagactttga ccagcgtgtc atggaacact 840 tcatcaaact gtacaaaaag aagacgggca aagatgtcag gaaagacaat agagctgtgc 900 agaaactccg gcgcgaggta gaaaaggcca aacgggccct gtcttctcag catcaagcaa 960 gaattgaaat tgagtccttc tatgaaggag aagac 995 <210> 31 <211> 1046 <212> DNA < 213> Artificial Sequence <220> <223> pcDNA3.1 GRP78 reverse <400> 31 tctatgaagg agaagacttt tctgagaccc tgactcggg c caaatttgaa gagctcaaca 60 tggatctgtt ccggtctact atgaagcccg tccagaaagt gttggaagat tctgatttga 120 agaagtctga tattgatgaa attgttcttg ttggtggctc gactcgaatt ccaaagattc 180 agcaactggt taaagagttc ttcaatggca aggaaccatc ccgtggcata aacccagatg 240 aagctgtagc gtatggtgct gctgtccagg ctggtgtgct ctctggtgat caagatacag 300 gtgacctggt actgcttgat gtatgtcccc ttacacttgg tattgaaact gtgggaggtg 360 tcatgaccaa actgattcca aggaacacag tggtgcctac caagaagtct cagatctttt 420 ctacagcttc tgataatcaa ccaactgtta caatcaaggt ctatgaaggt gaaagacccc 480 tgacaaaaga caatcatctt ctgggtacat ttgatctgac tggaattcct cctgctcctc 540 gtggggtccc acagattgaa gtcacctttg agatagatgt gaatggtatt cttcgagtga 600 cagctgaaga caagggtaca gggaacaaaa ataagatcac aatcaccaat gaccagaatc 660 gcctgacacc tgaagaaatc gaaaggatgg ttaatgatgc tgagaagttt gctgaggaag 720 acaaaaagct caaggagcgc attgatacta gaaatgagtt ggaaagctat gcctattctc 780 taaagaatca gattggagat aaagaaaagc tgggaggtaa actttcctct gaagataagg 840 agaccatgga aaaagctgta gaagaaaaga ttgaatggct ggaaagccac caagatgc tg 900 acattgaaga cttcaaagct aagaagaagg aactggaaga aattgttcaa ccaattatca 960 gcaaactcta tggaagtgca ggccctcccc caactggtga agaggataca gcagaaaaag 1020atgagttgta gtctagagtc ccgtaa 1046

Claims (16)

GRP78(Glucose regulated protein 78) 유전자가 도입된, 종양 표적능이 향상된 종양 살상 바이러스 전달용 중간엽 줄기세포.
GRP78 (Glucose regulated protein 78) gene introduced, mesenchymal stem cells for oncolytic virus delivery with improved tumor targeting ability.
발현 유도 물질에 의해 발현이 유도되도록 E1B55K 유전자가 도입된 종양 살상 바이러스 바이러스 전달용 중간엽 줄기세포.
A mesenchymal stem cell for oncolytic virus delivery into which the E1B55K gene is introduced so that expression is induced by an expression inducer.
GRP78(Glucose regulated protein 78) 유전자 및 E1B55K 유전자를 포함하며, 상기 E1B55K 유전자는 발현유도물질에 의해 발현되는 것인 종양 살상 바이러스 바이러스 전달용 중간엽 줄기세포.
It includes a GRP78 (Glucose regulated protein 78) gene and an E1B55K gene, wherein the E1B55K gene is expressed by an expression inducer. Mesenchymal stem cells for oncolytic virus virus delivery.
제 1 항 내지 제 3 항 중 어느 한 항에 있어서,
TERT(telomerase reverse transcriptase) 유전자가 추가로 도입된 중간엽 줄기세포.
4. The method according to any one of claims 1 to 3,
TERT (telomerase reverse transcriptase) gene is additionally introduced mesenchymal stem cells.
제 1 항 내지 제 3 항 중 어느 한 항에 있어서,
상기 종양 살상 바이러스는 종양 살상 아데노바이러스, 종양 살상 아데노-관련 바이러스(Adeno-associated viruses, AAV), 종양 살상 레트로바이러스, 종양 살상 렌티바이러스, 종양 살상 헤르페스 심플렉스 바이러스 또는 종양 살상 백시니아 바이러스인 중간엽 줄기세포.
4. The method according to any one of claims 1 to 3,
The oncolytic virus is mesenchymal which is an oncolytic adenovirus, oncolytic adeno-associated viruses (AAV), oncolytic retrovirus, oncolytic lentivirus, oncolytic herpes simplex virus or oncolytic vaccinia virus. Stem Cells.
제 1 항 내지 제 3 항 중 어느 한 항에 있어서,
상기 종양 살상 바이러스는 종양 살상 아데노바이러스인 중간엽 줄기세포.
4. The method according to any one of claims 1 to 3,
The oncolytic virus is an oncolytic adenovirus mesenchymal stem cells.
제 2 항 또는 제 3 항에 있어서,
E1B55K 유전자는 중간엽 줄기세포의 체내 도입 후 발현되는 것인 중간엽 줄기세포.
4. The method according to claim 2 or 3,
The E1B55K gene is mesenchymal stem cells that are expressed after introduction of the mesenchymal stem cells into the body.
제 2 항 또는 제 3 항에 있어서,
발현유도물질은 독시사이클린 또는 테트라사이클린인 중간엽 줄기세포.
4. The method according to claim 2 or 3,
The expression inducer is doxycycline or tetracycline mesenchymal stem cells.
제 1 항 내지 제 3 항 중 어느 한 항에 있어서,
인간 유래 중간엽 줄기세포주.
4. The method according to any one of claims 1 to 3,
A human-derived mesenchymal stem cell line.
제 1 항 내지 제 3 항 중 어느 한 항에 있어서,
제대혈, 골수 또는 지방 유래인 중간엽 줄기세포주.
4. The method according to any one of claims 1 to 3,
A mesenchymal stem cell line derived from cord blood, bone marrow or adipose.
청구항 1 내지 청구항 3 중 어느 한 항의 중간엽 줄기세포 및 종양 살상 바이러스를 포함하는 항암 유전자 전달용 조성물.
A composition for anticancer gene delivery comprising the mesenchymal stem cells of any one of claims 1 to 3 and an oncolytic virus.
제 11 항에 있어서,
상기 암은 위암, 폐암, 유방암, 난소암, 간암, 기관지암, 비인두암, 후두암, 췌장암, 담도암, 방광암, 대장암, 결장암, 자궁경부암, 뇌암, 전립선암, 골암, 두경부암, 피부암, 신장암, 배수성암(polyploid carcinoma), 갑상선암, 부갑상선암 또는 요관암인 유전자 전달용 조성물.
12. The method of claim 11,
The cancer is stomach cancer, lung cancer, breast cancer, ovarian cancer, liver cancer, bronchial cancer, nasopharyngeal cancer, laryngeal cancer, pancreatic cancer, biliary tract cancer, bladder cancer, colorectal cancer, colon cancer, cervical cancer, brain cancer, prostate cancer, bone cancer, head and neck cancer, skin cancer, kidney A composition for gene delivery that is cancer, polyploid carcinoma, thyroid cancer, parathyroid cancer or ureter cancer.
청구항 1 내지 청구항 3 중 어느 한 항의 중간엽 줄기세포 및 종양 살상 바이러스를 포함하는 항암용 약제학적 조성물.
A pharmaceutical composition for anticancer comprising the mesenchymal stem cells of any one of claims 1 to 3 and an oncolytic virus.
제 13 항에 있어서,
상기 암은 위암, 폐암, 유방암, 난소암, 간암, 기관지암, 비인두암, 후두암, 췌장암, 담도암, 방광암, 대장암, 결장암, 자궁경부암, 뇌암, 전립선암, 골암, 두경부암, 피부암, 신장암, 배수성암(polyploid carcinoma), 갑상선암, 부갑상선암 또는 요관암인 약제학적 조성물.
14. The method of claim 13,
The cancer is stomach cancer, lung cancer, breast cancer, ovarian cancer, liver cancer, bronchial cancer, nasopharyngeal cancer, laryngeal cancer, pancreatic cancer, biliary tract cancer, bladder cancer, colorectal cancer, colon cancer, cervical cancer, brain cancer, prostate cancer, bone cancer, head and neck cancer, skin cancer, kidney A pharmaceutical composition which is cancer, polyploid carcinoma, thyroid cancer, parathyroid cancer or ureter cancer.
청구항 1 내지 청구항 3 중 어느 한 항에 따른 중간엽 줄기세포 및 종양 살상 바이러스를 포함하는 암 진단용 조성물.
A composition for diagnosing cancer comprising mesenchymal stem cells and an oncolytic virus according to any one of claims 1 to 3.
제 15 항에 있어서,
상기 암은 위암, 폐암, 유방암, 난소암, 간암, 기관지암, 비인두암, 후두암, 췌장암, 담도암, 방광암, 대장암, 결장암, 자궁경부암, 뇌암, 전립선암, 골암, 두경부암, 피부암, 신장암, 배수성암(polyploid carcinoma), 갑상선암, 부갑상선암 또는 요관암인 암 진단용 조성물.
16. The method of claim 15,
The cancer is stomach cancer, lung cancer, breast cancer, ovarian cancer, liver cancer, bronchial cancer, nasopharyngeal cancer, laryngeal cancer, pancreatic cancer, biliary tract cancer, bladder cancer, colorectal cancer, colon cancer, cervical cancer, brain cancer, prostate cancer, bone cancer, head and neck cancer, skin cancer, kidney A composition for diagnosing cancer, which is cancer, polyploid carcinoma, thyroid cancer, parathyroid cancer or ureter cancer.
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Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
KR20170067667A (en) * 2015-12-08 2017-06-16 연세대학교 산학협력단 Composition including GMCSF gene Flt3L-TRAIL fusion gene shRNA downregulating TGF and shRNA downregulating HSP for treatment of malignant tumor
WO2019093435A1 (en) * 2017-11-08 2019-05-16 国立大学法人 鹿児島大学 Oncolytic virus (oncolytic immunotherapy) capable of effectively treating even metastatic cancer while ensuring safety, with expression control system providing optimal expression level of mounted immunogenic gene
KR20190139763A (en) * 2018-06-08 2019-12-18 연세대학교 산학협력단 Mesenchymal stem cell line capable of adenoviral infection and replication

Family Cites Families (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
SG11202005509YA (en) * 2017-12-13 2020-07-29 Genemedicine Co Ltd Recombinant adenoviruses and stem cells comprising same
WO2019235771A1 (en) * 2018-06-08 2019-12-12 연세대학교 산학협력단 Mesenchymal stem cell line in which infection and replication of adenovirus are enabled

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
KR20170067667A (en) * 2015-12-08 2017-06-16 연세대학교 산학협력단 Composition including GMCSF gene Flt3L-TRAIL fusion gene shRNA downregulating TGF and shRNA downregulating HSP for treatment of malignant tumor
WO2019093435A1 (en) * 2017-11-08 2019-05-16 国立大学法人 鹿児島大学 Oncolytic virus (oncolytic immunotherapy) capable of effectively treating even metastatic cancer while ensuring safety, with expression control system providing optimal expression level of mounted immunogenic gene
KR20190139763A (en) * 2018-06-08 2019-12-18 연세대학교 산학협력단 Mesenchymal stem cell line capable of adenoviral infection and replication
KR102169798B1 (en) 2018-06-08 2020-10-26 연세대학교 산학협력단 Mesenchymal stem cell line capable of adenoviral infection and replication

Non-Patent Citations (4)

* Cited by examiner, † Cited by third party
Title
Kerrigan BCP, Shimizu Y, Andreeff M, Lang FF. Mesenchymal stromal cells for the delivery of oncolytic viruses in gliomas. Cytotherapy 2017; 19:445-457
Nakashima H, Kaur B, Chiocca EA. Directing systemic oncolytic viral delivery to tumors via carrier cells. Cytokine Growth Factor Rev 2010; 21:119-126
Silva, N et al., Double trouble for tumors: Exploiting the tumor microenvironment to enhance anticancer effect of oncolytic viruses, Cytokine & Growth Factor Reviews 21: 135, 2010
Xia, X et al, Mesenchymal stem cells as carriers and amplifiers in CRAd delivery to tumors, Molecular Cancer 10: 134, 2011

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